1 | ! $Id: lwu.F90 5185 2024-09-11 14:27:07Z fhourdin $ |
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2 | |
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3 | SUBROUTINE LWU & |
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4 | & (KIDIA, KFDIA, KLON, KLEV, & |
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5 | & PAER, PCCO2, PDP, PPMB, PQOF, PTAVE, PVIEW, PWV, & |
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6 | & PABCU & |
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7 | &) |
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8 | |
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9 | !**** *LWU* - LONGWAVE EFFECTIVE ABSORBER AMOUNTS |
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10 | |
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11 | ! PURPOSE. |
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12 | ! -------- |
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13 | ! COMPUTES ABSORBER AMOUNTS INCLUDING PRESSURE AND |
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14 | ! TEMPERATURE EFFECTS |
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15 | |
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16 | !** INTERFACE. |
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17 | ! ---------- |
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18 | |
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19 | ! EXPLICIT ARGUMENTS : |
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20 | ! -------------------- |
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21 | ! ==== INPUTS === |
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22 | ! PAER : (KLON,6,KLEV) ; OPTICAL THICKNESS OF THE AEROSOLS |
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23 | ! PCCO2 : ; CONCENTRATION IN CO2 (PA/PA) |
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24 | ! PDP : (KLON,KLEV) ; LAYER PRESSURE THICKNESS (PA) |
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25 | ! PPMB : (KLON,KLEV+1) ; HALF LEVEL PRESSURE |
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26 | ! PQOF : (KLON,KLEV) ; CONCENTRATION IN OZONE (PA/PA) |
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27 | ! PTAVE : (KLON,KLEV) ; TEMPERATURE |
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28 | ! PWV : (KLON,KLEV) ; SPECIFIC HUMIDITY PA/PA |
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29 | ! PVIEW : (KLON) ; COSECANT OF VIEWING ANGLE |
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30 | ! ==== OUTPUTS === |
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31 | ! PABCU :(KLON,NUA,3*KLEV+1); EFFECTIVE ABSORBER AMOUNTS |
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32 | |
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33 | ! IMPLICIT ARGUMENTS : NONE |
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34 | ! -------------------- |
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35 | |
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36 | ! METHOD. |
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37 | ! ------- |
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38 | |
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39 | ! 1. COMPUTES THE PRESSURE AND TEMPERATURE WEIGHTED AMOUNTS OF |
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40 | ! ABSORBERS. |
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41 | |
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42 | ! EXTERNALS. |
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43 | ! ---------- |
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44 | |
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45 | ! NONE |
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46 | |
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47 | ! REFERENCE. |
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48 | ! ---------- |
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49 | |
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50 | ! SEE RADIATION'S PART OF THE MODEL'S DOCUMENTATION AND |
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51 | ! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS |
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52 | |
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53 | ! AUTHOR. |
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54 | ! ------- |
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55 | ! JEAN-JACQUES MORCRETTE *ECMWF* |
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56 | |
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57 | ! MODIFICATIONS. |
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58 | ! -------------- |
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59 | ! ORIGINAL : 89-07-14 |
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60 | ! JJ Morcrette 97-04-18 Revised Continuum + Clean-up |
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61 | ! M.Hamrud 01-Oct-2003 CY28 Cleaning |
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62 | |
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63 | !----------------------------------------------------------------------- |
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64 | |
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65 | USE PARKIND1, ONLY: JPIM, JPRB |
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66 | USE YOMHOOK, ONLY: LHOOK, DR_HOOK |
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67 | |
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68 | USE YOMCST, ONLY: RG |
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69 | USE YOESW, ONLY: RAER |
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70 | USE YOELW, ONLY: NSIL, NUA, NG1, NG1P1, & |
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71 | & ALWT, BLWT, RO3T, RT1, TREF, & |
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72 | & RVGCO2, RVGH2O, RVGO3 |
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73 | !USE YOERDI , ONLY : RCH4 ,RN2O ,RCFC11 ,RCFC12 |
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74 | USE YOERDU, ONLY: R10E, REPSCO, REPSCQ |
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75 | USE lmdz_cppkeys_wrapper, ONLY: CPPKEY_REPROBUS |
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76 | USE lmdz_reprobus_wrappers, ONLY: rch42d, rn2o2d, rcfc112d, rcfc122d, ok_rtime2d |
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77 | USE infotrac_phy, ONLY: type_trac |
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78 | USE lmdz_clesphys |
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79 | |
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80 | IMPLICIT NONE |
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81 | |
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82 | INTEGER(KIND = JPIM), INTENT(IN) :: KLON |
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83 | INTEGER(KIND = JPIM), INTENT(IN) :: KLEV |
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84 | INTEGER(KIND = JPIM), INTENT(IN) :: KIDIA |
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85 | INTEGER(KIND = JPIM), INTENT(IN) :: KFDIA |
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86 | REAL(KIND = JPRB), INTENT(IN) :: PAER(KLON, 6, KLEV) |
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87 | REAL(KIND = JPRB), INTENT(IN) :: PCCO2 |
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88 | REAL(KIND = JPRB), INTENT(IN) :: PDP(KLON, KLEV) |
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89 | REAL(KIND = JPRB), INTENT(IN) :: PPMB(KLON, KLEV + 1) |
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90 | REAL(KIND = JPRB), INTENT(IN) :: PQOF(KLON, KLEV) |
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91 | REAL(KIND = JPRB), INTENT(IN) :: PTAVE(KLON, KLEV) |
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92 | REAL(KIND = JPRB), INTENT(IN) :: PVIEW(KLON) |
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93 | REAL(KIND = JPRB), INTENT(IN) :: PWV(KLON, KLEV) |
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94 | REAL(KIND = JPRB), INTENT(OUT) :: PABCU(KLON, NUA, 3 * KLEV + 1) |
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95 | |
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96 | !----------------------------------------------------------------------- |
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97 | |
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98 | !* 0.1 ARGUMENTS |
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99 | ! --------- |
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100 | |
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101 | !----------------------------------------------------------------------- |
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102 | |
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103 | ! ------------ |
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104 | REAL(KIND = JPRB) :: ZABLY(KLON, 7, 3 * KLEV + 1), ZDPM(KLON, 3 * KLEV)& |
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105 | &, ZDUC(KLON, 3 * KLEV + 1), ZFACT(KLON)& |
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106 | &, ZUPM(KLON, 3 * KLEV) |
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107 | REAL(KIND = JPRB) :: ZPHIO(KLON), ZPSC2(KLON), ZPSC3(KLON), ZPSH1(KLON)& |
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108 | &, ZPSH2(KLON), ZPSH3(KLON), ZPSH4(KLON), ZPSH5(KLON)& |
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109 | &, ZPSH6(KLON), ZPSIO(KLON), ZTCON(KLON)& |
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110 | &, ZPHM6(KLON), ZPSM6(KLON), ZPHN6(KLON), ZPSN6(KLON) |
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111 | REAL(KIND = JPRB) :: ZSSIG(KLON, 3 * KLEV + 1), ZTAVI(KLON)& |
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112 | &, ZUAER(KLON, NSIL), ZXOZ(KLON), ZXWV(KLON) |
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113 | |
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114 | INTEGER(KIND = JPIM) :: IAE1, IAE2, IAE3, IC, ICP1, IG1, IJ, IJPN, & |
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115 | & IKIP1, IKJ, IKJP, IKJPN, IKJR, IKL, JA, JAE, & |
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116 | & JK, JKI, JKK, JL |
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117 | |
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118 | REAL(KIND = JPRB) :: ZALUP, ZCAC8, ZCAH1, ZCAH2, ZCAH3, ZCAH4, & |
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119 | & ZCAH5, ZCAH6, ZCBC8, ZCBH1, ZCBH2, ZCBH3, & |
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120 | & ZCBH4, ZCBH5, ZCBH6, ZDIFF, ZDPMG, ZDPMP0, & |
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121 | & ZFPPW, ZTX, ZTX2, ZU6, ZUP, ZUPMCO2, ZUPMG, & |
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122 | & ZUPMH2O, ZUPMO3, ZZABLY |
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123 | REAL(KIND = JPRB) :: ZHOOK_HANDLE |
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124 | |
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125 | |
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126 | !----------------------------------------------------------------------- |
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127 | |
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128 | !* 1. INITIALIZATION |
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129 | ! -------------- |
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130 | |
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131 | !----------------------------------------------------------------------- |
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132 | |
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133 | !* 2. PRESSURE OVER GAUSS SUB-LEVELS |
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134 | ! ------------------------------ |
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135 | |
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136 | IF (LHOOK) CALL DR_HOOK('LWU', 0, ZHOOK_HANDLE) |
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137 | DO JL = KIDIA, KFDIA |
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138 | ZSSIG(JL, 1) = PPMB(JL, 1) * 100._JPRB |
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139 | ENDDO |
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140 | |
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141 | DO JK = 1, KLEV |
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142 | IKJ = (JK - 1) * NG1P1 + 1 |
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143 | IKJR = IKJ |
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144 | IKJP = IKJ + NG1P1 |
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145 | DO JL = KIDIA, KFDIA |
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146 | ZSSIG(JL, IKJP) = PPMB(JL, JK + 1) * 100._JPRB |
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147 | ENDDO |
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148 | DO IG1 = 1, NG1 |
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149 | IKJ = IKJ + 1 |
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150 | DO JL = KIDIA, KFDIA |
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151 | ZSSIG(JL, IKJ) = (ZSSIG(JL, IKJR) + ZSSIG(JL, IKJP)) * 0.5_JPRB & |
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152 | & + RT1(IG1) * (ZSSIG(JL, IKJP) - ZSSIG(JL, IKJR)) * 0.5_JPRB |
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153 | ENDDO |
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154 | ENDDO |
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155 | ENDDO |
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156 | |
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157 | !----------------------------------------------------------------------- |
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158 | |
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159 | !* 4. PRESSURE THICKNESS AND MEAN PRESSURE OF SUB-LAYERS |
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160 | ! -------------------------------------------------- |
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161 | |
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162 | DO JKI = 1, 3 * KLEV |
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163 | IKIP1 = JKI + 1 |
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164 | DO JL = KIDIA, KFDIA |
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165 | ZUPM(JL, JKI) = (ZSSIG(JL, JKI) + ZSSIG(JL, IKIP1)) * 0.5_JPRB |
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166 | ZDPM(JL, JKI) = (ZSSIG(JL, JKI) - ZSSIG(JL, IKIP1)) / (10._JPRB * RG) |
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167 | ENDDO |
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168 | ENDDO |
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169 | |
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170 | DO JK = 1, KLEV |
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171 | IKL = KLEV + 1 - JK |
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172 | DO JL = KIDIA, KFDIA |
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173 | ZXWV(JL) = MAX (PWV(JL, IKL), REPSCQ) |
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174 | ZXOZ(JL) = MAX (PQOF(JL, IKL) / PDP(JL, IKL), REPSCO) |
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175 | ENDDO |
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176 | IKJ = (JK - 1) * NG1P1 + 1 |
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177 | IKJPN = IKJ + NG1 |
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178 | DO JKK = IKJ, IKJPN |
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179 | DO JL = KIDIA, KFDIA |
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180 | ZDPMG = ZDPM(JL, JKK) |
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181 | ZDPMP0 = ZDPMG / 101325._JPRB |
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182 | ZUPMG = ZUPM(JL, JKK) * ZDPMP0 |
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183 | ZUPMCO2 = (ZUPM(JL, JKK) + RVGCO2) * ZDPMP0 |
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184 | ZUPMH2O = (ZUPM(JL, JKK) + RVGH2O) * ZDPMP0 |
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185 | ZUPMO3 = (ZUPM(JL, JKK) + RVGO3) * ZDPMP0 |
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186 | ZDUC(JL, JKK) = ZDPMG |
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187 | ZABLY(JL, 6, JKK) = ZXOZ(JL) * ZDPMG |
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188 | ZABLY(JL, 7, JKK) = ZXOZ(JL) * ZUPMO3 |
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189 | ZU6 = ZXWV(JL) * ZUPMG |
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190 | ZFPPW = 1.6078_JPRB * ZXWV(JL) / (1.0_JPRB + 0.608_JPRB * ZXWV(JL)) |
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191 | ZABLY(JL, 1, JKK) = ZXWV(JL) * ZUPMH2O |
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192 | ZABLY(JL, 5, JKK) = ZU6 * ZFPPW |
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193 | ZABLY(JL, 4, JKK) = ZU6 * (1.0_JPRB - ZFPPW) |
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194 | ZABLY(JL, 3, JKK) = PCCO2 * ZUPMCO2 |
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195 | ZABLY(JL, 2, JKK) = PCCO2 * ZDPMG |
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196 | ENDDO |
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197 | ENDDO |
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198 | ENDDO |
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199 | |
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200 | !----------------------------------------------------------------------- |
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201 | |
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202 | !* 5. CUMULATIVE ABSORBER AMOUNTS FROM TOP OF ATMOSPHERE |
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203 | ! -------------------------------------------------- |
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204 | |
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205 | DO JA = 1, NUA |
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206 | DO JL = KIDIA, KFDIA |
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207 | PABCU(JL, JA, 3 * KLEV + 1) = 0.0_JPRB |
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208 | ENDDO |
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209 | ENDDO |
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210 | |
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211 | DO JK = 1, KLEV |
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212 | IJ = (JK - 1) * NG1P1 + 1 |
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213 | IJPN = IJ + NG1 |
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214 | IKL = KLEV + 1 - JK |
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215 | |
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216 | !* 5.1 CUMULATIVE AEROSOL AMOUNTS FROM TOP OF ATMOSPHERE |
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217 | ! -------------------------------------------------- |
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218 | ! -- NB: 'PAER' AEROSOLS ARE ENTERED FROM TOP TO BOTTOM |
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219 | |
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220 | IAE1 = 3 * KLEV + 1 - IJ |
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221 | IAE2 = 3 * KLEV + 1 - (IJ + 1) |
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222 | IAE3 = 3 * KLEV + 1 - IJPN |
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223 | ! PRINT *,'IAE1= ',IAE1 |
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224 | ! PRINT *,'IAE2= ',IAE2 |
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225 | ! PRINT *,'IAE3= ',IAE3 |
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226 | ! PRINT *,'KIDIA= ',KIDIA |
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227 | ! PRINT *,'KFDIA= ',KFDIA |
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228 | ! PRINT *,'KLEV= ',KLEV |
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229 | DO JAE = 1, 6 |
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230 | DO JL = KIDIA, KFDIA |
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231 | ! PRINT *,'JL= ',JL,'-JAE= ',JAE,'-JK= ',JK,'-NSIL= ',NSIL |
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232 | ZUAER(JL, JAE) = & |
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233 | & (RAER(JAE, 1) * PAER(JL, 1, JK) + RAER(JAE, 2) * PAER(JL, 2, JK)& |
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234 | & + RAER(JAE, 3) * PAER(JL, 3, JK) + RAER(JAE, 4) * PAER(JL, 4, JK)& |
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235 | & + RAER(JAE, 5) * PAER(JL, 5, JK) + RAER(JAE, 6) * PAER(JL, 6, JK))& |
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236 | & / (ZDUC(JL, IAE1) + ZDUC(JL, IAE2) + ZDUC(JL, IAE3)) |
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237 | ENDDO |
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238 | ENDDO |
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239 | |
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240 | !* 5.2 INTRODUCES TEMPERATURE EFFECTS ON ABSORBER AMOUNTS |
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241 | ! -------------------------------------------------- |
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242 | |
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243 | DO JL = KIDIA, KFDIA |
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244 | ZTAVI(JL) = PTAVE(JL, IKL) |
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245 | ZFACT(JL) = 1.0_JPRB - ZTAVI(JL) / 296._JPRB |
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246 | ZTCON(JL) = EXP(6.08_JPRB * (296._JPRB / ZTAVI(JL) - 1.0_JPRB)) |
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247 | ! ZTCON(JL)=EXP(6.08*ZFACT(JL)) |
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248 | ZTX = ZTAVI(JL) - TREF |
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249 | ZTX2 = ZTX * ZTX |
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250 | ZZABLY = ZABLY(JL, 1, IAE1) + ZABLY(JL, 1, IAE2) + ZABLY(JL, 1, IAE3) |
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251 | ZUP = MIN(MAX(0.5_JPRB * R10E * LOG(ZZABLY) + 5._JPRB, 0.0_JPRB), 6.0_JPRB) |
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252 | ZCAH1 = ALWT(1, 1) + ZUP * (ALWT(1, 2) + ZUP * (ALWT(1, 3))) |
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253 | ZCBH1 = BLWT(1, 1) + ZUP * (BLWT(1, 2) + ZUP * (BLWT(1, 3))) |
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254 | ZPSH1(JL) = EXP(ZCAH1 * ZTX + ZCBH1 * ZTX2) |
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255 | ZCAH2 = ALWT(2, 1) + ZUP * (ALWT(2, 2) + ZUP * (ALWT(2, 3))) |
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256 | ZCBH2 = BLWT(2, 1) + ZUP * (BLWT(2, 2) + ZUP * (BLWT(2, 3))) |
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257 | ZPSH2(JL) = EXP(ZCAH2 * ZTX + ZCBH2 * ZTX2) |
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258 | ZCAH3 = ALWT(3, 1) + ZUP * (ALWT(3, 2) + ZUP * (ALWT(3, 3))) |
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259 | ZCBH3 = BLWT(3, 1) + ZUP * (BLWT(3, 2) + ZUP * (BLWT(3, 3))) |
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260 | ZPSH3(JL) = EXP(ZCAH3 * ZTX + ZCBH3 * ZTX2) |
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261 | ZCAH4 = ALWT(4, 1) + ZUP * (ALWT(4, 2) + ZUP * (ALWT(4, 3))) |
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262 | ZCBH4 = BLWT(4, 1) + ZUP * (BLWT(4, 2) + ZUP * (BLWT(4, 3))) |
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263 | ZPSH4(JL) = EXP(ZCAH4 * ZTX + ZCBH4 * ZTX2) |
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264 | ZCAH5 = ALWT(5, 1) + ZUP * (ALWT(5, 2) + ZUP * (ALWT(5, 3))) |
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265 | ZCBH5 = BLWT(5, 1) + ZUP * (BLWT(5, 2) + ZUP * (BLWT(5, 3))) |
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266 | ZPSH5(JL) = EXP(ZCAH5 * ZTX + ZCBH5 * ZTX2) |
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267 | ZCAH6 = ALWT(6, 1) + ZUP * (ALWT(6, 2) + ZUP * (ALWT(6, 3))) |
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268 | ZCBH6 = BLWT(6, 1) + ZUP * (BLWT(6, 2) + ZUP * (BLWT(6, 3))) |
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269 | ZPSH6(JL) = EXP(ZCAH6 * ZTX + ZCBH6 * ZTX2) |
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270 | ZPHM6(JL) = EXP(-5.81E-4_JPRB * ZTX - 1.13E-6_JPRB * ZTX2) |
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271 | ZPSM6(JL) = EXP(-5.57E-4_JPRB * ZTX - 3.30E-6_JPRB * ZTX2) |
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272 | ZPHN6(JL) = EXP(-3.46E-5_JPRB * ZTX + 2.05E-7_JPRB * ZTX2) |
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273 | ZPSN6(JL) = EXP(3.70E-3_JPRB * ZTX - 2.30E-6_JPRB * ZTX2) |
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274 | ENDDO |
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275 | |
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276 | DO JL = KIDIA, KFDIA |
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277 | ZTAVI(JL) = PTAVE(JL, IKL) |
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278 | ZTX = ZTAVI(JL) - TREF |
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279 | ZTX2 = ZTX * ZTX |
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280 | ZZABLY = ZABLY(JL, 3, IAE1) + ZABLY(JL, 3, IAE2) + ZABLY(JL, 3, IAE3) |
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281 | ZALUP = R10E * LOG (ZZABLY) |
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282 | ZUP = MAX(0.0_JPRB, 5.0_JPRB + 0.5_JPRB * ZALUP) |
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283 | ZPSC2(JL) = (ZTAVI(JL) / TREF) ** ZUP |
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284 | ZCAC8 = ALWT(8, 1) + ZUP * (ALWT(8, 2) + ZUP * (ALWT(8, 3))) |
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285 | ZCBC8 = BLWT(8, 1) + ZUP * (BLWT(8, 2) + ZUP * (BLWT(8, 3))) |
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286 | ZPSC3(JL) = EXP(ZCAC8 * ZTX + ZCBC8 * ZTX2) |
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287 | ZPHIO(JL) = EXP(RO3T(1) * ZTX + RO3T(2) * ZTX2) |
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288 | ZPSIO(JL) = EXP(2.0_JPRB * (RO3T(3) * ZTX + RO3T(4) * ZTX2)) |
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289 | ENDDO |
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290 | |
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291 | DO JKK = IJ, IJPN |
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292 | IC = 3 * KLEV + 1 - JKK |
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293 | ICP1 = IC + 1 |
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294 | DO JL = KIDIA, KFDIA |
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295 | ZDIFF = PVIEW(JL) |
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296 | !- H2O continuum |
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297 | PABCU(JL, 10, IC) = PABCU(JL, 10, ICP1) + ZABLY(JL, 4, IC) * ZDIFF |
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298 | PABCU(JL, 11, IC) = PABCU(JL, 11, ICP1) + ZABLY(JL, 5, IC) * ZTCON(JL) * ZDIFF |
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299 | !- O3 |
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300 | PABCU(JL, 12, IC) = PABCU(JL, 12, ICP1) + ZABLY(JL, 6, IC) * ZPHIO(JL) * ZDIFF |
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301 | PABCU(JL, 13, IC) = PABCU(JL, 13, ICP1) + ZABLY(JL, 7, IC) * ZPSIO(JL) * ZDIFF |
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302 | !- CO2 |
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303 | PABCU(JL, 7, IC) = PABCU(JL, 7, ICP1) + ZABLY(JL, 3, IC) * ZPSC2(JL) * ZDIFF |
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304 | PABCU(JL, 8, IC) = PABCU(JL, 8, ICP1) + ZABLY(JL, 3, IC) * ZPSC3(JL) * ZDIFF |
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305 | PABCU(JL, 9, IC) = PABCU(JL, 9, ICP1) + ZABLY(JL, 3, IC) * ZPSC3(JL) * ZDIFF |
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306 | !- H2O |
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307 | PABCU(JL, 1, IC) = PABCU(JL, 1, ICP1) + ZABLY(JL, 1, IC) * ZPSH1(JL) |
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308 | PABCU(JL, 2, IC) = PABCU(JL, 2, ICP1) + ZABLY(JL, 1, IC) * ZPSH2(JL) |
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309 | PABCU(JL, 3, IC) = PABCU(JL, 3, ICP1) + ZABLY(JL, 1, IC) * ZPSH5(JL) * ZDIFF |
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310 | PABCU(JL, 4, IC) = PABCU(JL, 4, ICP1) + ZABLY(JL, 1, IC) * ZPSH3(JL) |
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311 | PABCU(JL, 5, IC) = PABCU(JL, 5, ICP1) + ZABLY(JL, 1, IC) * ZPSH4(JL) |
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312 | PABCU(JL, 6, IC) = PABCU(JL, 6, ICP1) + ZABLY(JL, 1, IC) * ZPSH6(JL) * ZDIFF |
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313 | !- aerosols |
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314 | PABCU(JL, 14, IC) = PABCU(JL, 14, ICP1) + ZUAER(JL, 1) * ZDUC(JL, IC) * ZDIFF |
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315 | PABCU(JL, 15, IC) = PABCU(JL, 15, ICP1) + ZUAER(JL, 2) * ZDUC(JL, IC) * ZDIFF |
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316 | PABCU(JL, 16, IC) = PABCU(JL, 16, ICP1) + ZUAER(JL, 3) * ZDUC(JL, IC) * ZDIFF |
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317 | PABCU(JL, 17, IC) = PABCU(JL, 17, ICP1) + ZUAER(JL, 4) * ZDUC(JL, IC) * ZDIFF |
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318 | PABCU(JL, 18, IC) = PABCU(JL, 18, ICP1) + ZUAER(JL, 5) * ZDUC(JL, IC) * ZDIFF |
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319 | IF (CPPKEY_REPROBUS .AND. type_trac=='repr'.AND. ok_rtime2d) THEN |
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320 | !- CH4 |
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321 | PABCU(JL, 19, IC) = PABCU(JL, 19, ICP1)& |
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322 | & + ZABLY(JL, 2, IC) * RCH42D(JL, IC) / PCCO2 * ZPHM6(JL) * ZDIFF |
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323 | PABCU(JL, 20, IC) = PABCU(JL, 20, ICP1)& |
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324 | & + ZABLY(JL, 3, IC) * RCH42D(JL, IC) / PCCO2 * ZPSM6(JL) * ZDIFF |
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325 | !- N2O |
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326 | PABCU(JL, 21, IC) = PABCU(JL, 21, ICP1)& |
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327 | & + ZABLY(JL, 2, IC) * RN2O2D(JL, IC) / PCCO2 * ZPHN6(JL) * ZDIFF |
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328 | PABCU(JL, 22, IC) = PABCU(JL, 22, ICP1)& |
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329 | & + ZABLY(JL, 3, IC) * RN2O2D(JL, IC) / PCCO2 * ZPSN6(JL) * ZDIFF |
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330 | !- CFC11 |
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331 | PABCU(JL, 23, IC) = PABCU(JL, 23, ICP1)& |
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332 | & + ZABLY(JL, 2, IC) * RCFC112D(JL, IC) / PCCO2 * ZDIFF |
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333 | !- CFC12 |
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334 | PABCU(JL, 24, IC) = PABCU(JL, 24, ICP1)& |
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335 | & + ZABLY(JL, 2, IC) * RCFC122D(JL, IC) / PCCO2 * ZDIFF |
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336 | |
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337 | ELSE |
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338 | !- CH4 |
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339 | PABCU(JL, 19, IC) = PABCU(JL, 19, ICP1)& |
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340 | & + ZABLY(JL, 2, IC) * RCH4 / PCCO2 * ZPHM6(JL) * ZDIFF |
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341 | PABCU(JL, 20, IC) = PABCU(JL, 20, ICP1)& |
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342 | & + ZABLY(JL, 3, IC) * RCH4 / PCCO2 * ZPSM6(JL) * ZDIFF |
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343 | !- N2O |
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344 | PABCU(JL, 21, IC) = PABCU(JL, 21, ICP1)& |
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345 | & + ZABLY(JL, 2, IC) * RN2O / PCCO2 * ZPHN6(JL) * ZDIFF |
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346 | PABCU(JL, 22, IC) = PABCU(JL, 22, ICP1)& |
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347 | & + ZABLY(JL, 3, IC) * RN2O / PCCO2 * ZPSN6(JL) * ZDIFF |
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348 | !- CFC11 |
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349 | PABCU(JL, 23, IC) = PABCU(JL, 23, ICP1)& |
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350 | & + ZABLY(JL, 2, IC) * RCFC11 / PCCO2 * ZDIFF |
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351 | !- CFC12 |
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352 | PABCU(JL, 24, IC) = PABCU(JL, 24, ICP1)& |
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353 | & + ZABLY(JL, 2, IC) * RCFC12 / PCCO2 * ZDIFF |
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354 | END IF |
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355 | ENDDO |
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356 | ENDDO |
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357 | |
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358 | ENDDO |
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359 | ! PRINT *,'END OF LWU' |
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360 | |
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361 | |
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362 | |
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363 | !----------------------------------------------------------------------- |
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364 | |
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365 | IF (LHOOK) CALL DR_HOOK('LWU', 1, ZHOOK_HANDLE) |
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366 | END SUBROUTINE LWU |
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