1 | MODULE updatereffrad_mod |
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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 updatereffrad(ngrid,nlayer, |
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8 | & rdust,rstormdust,rice,nuice, |
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9 | & reffrad,nueffrad, |
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10 | & pq,tauscaling,tau,pplay) |
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11 | USE updaterad, ONLY: updaterdust, updaterice_micro, |
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12 | & updaterice_typ |
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13 | use tracer_mod, only: nqmx, igcm_dust_mass, igcm_dust_number, |
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14 | & igcm_h2o_ice, igcm_ccn_mass, radius, |
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15 | & igcm_ccn_number, nuice_ref, varian, |
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16 | & ref_r0, igcm_dust_submicron, |
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17 | & igcm_stormdust_mass,igcm_stormdust_number |
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18 | USE dimradmars_mod, only: nueffdust,naerkind, |
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19 | & name_iaer, |
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20 | & iaer_dust_conrath,iaer_dust_doubleq, |
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21 | & iaer_dust_submicron,iaer_h2o_ice, |
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22 | & iaer_stormdust_doubleq |
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23 | |
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24 | IMPLICIT NONE |
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25 | c======================================================================= |
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26 | c subject: |
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27 | c -------- |
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28 | c Subroutine designed to update the aerosol size distribution used by |
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29 | c the radiative transfer scheme. This size distribution is assumed |
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30 | c to be a log-normal distribution, with effective radius "reffrad" and |
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31 | c variance "nueffrad". |
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32 | c At firstcall, "rice" and "nuice" are not known, because |
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33 | c the H2O ice microphysical scheme is called after the radiative |
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34 | c transfer in physiq.F. That's why we assess the size of the |
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35 | c water-ice particles at firstcall (see part 1.2 below). |
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36 | c |
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37 | c author: |
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38 | c ------ |
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39 | c J.-B. Madeleine (2009-2010) |
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40 | c |
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41 | c======================================================================= |
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42 | c |
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43 | c Declarations : |
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44 | c ------------- |
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45 | c |
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46 | include "callkeys.h" |
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47 | |
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48 | c----------------------------------------------------------------------- |
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49 | c Inputs/outputs: |
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50 | c ------ |
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51 | |
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52 | INTEGER, INTENT(in) :: ngrid,nlayer |
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53 | c Ice geometric mean radius (m) |
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54 | REAL, INTENT(out) :: rice(ngrid,nlayer) |
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55 | c Estimated effective variance of the size distribution (n.u.) |
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56 | REAL, INTENT(out) :: nuice(ngrid,nlayer) |
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57 | c Tracer mass mixing ratio (kg/kg) |
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58 | REAL, INTENT(in) :: pq(ngrid,nlayer,nqmx) |
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59 | REAL, INTENT(out) :: rdust(ngrid,nlayer) ! Dust geometric mean radius (m) |
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60 | REAL, INTENT(out) :: rstormdust(ngrid,nlayer) ! Dust geometric mean radius (m) |
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61 | REAL, INTENT(in) :: pplay(ngrid,nlayer) ! altitude at the middle of the layers |
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62 | REAL, INTENT(in) :: tau(ngrid,naerkind) |
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63 | c Aerosol effective radius used for radiative transfer (meter) |
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64 | REAL, INTENT(out) :: reffrad(ngrid,nlayer,naerkind) |
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65 | c Aerosol effective variance used for radiative transfer (n.u.) |
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66 | REAL, INTENT(out) :: nueffrad(ngrid,nlayer,naerkind) |
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67 | REAL, INTENT(in) :: tauscaling(ngrid) ! Convertion factor for qccn and Nccn |
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68 | |
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69 | c Local variables: |
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70 | c --------------- |
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71 | |
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72 | INTEGER :: ig,l ! 3D grid indices |
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73 | INTEGER :: iaer ! Aerosol index |
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74 | |
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75 | c Number of cloud condensation nuclei near the surface |
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76 | c (only used at firstcall). This value is taken from |
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77 | c Montmessin et al. 2004 JGR 109 E10004 p5 (2E6 part m-3), and |
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78 | c converted to part kg-1 using a typical atmospheric density. |
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79 | |
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80 | REAL, PARAMETER :: ccn0 = 1.3E8 |
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81 | |
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82 | c For microphysics only: |
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83 | REAL Mo,No ! Mass and number of ccn |
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84 | REAL rhocloud(ngrid,nlayer) ! Cloud density (kg.m-3) |
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85 | |
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86 | LOGICAL,SAVE :: firstcall=.true. |
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87 | |
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88 | REAL CBRT |
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89 | EXTERNAL CBRT |
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90 | |
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91 | c================================================================== |
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92 | c 1. Update radius from fields from dynamics or initial state |
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93 | c================================================================== |
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94 | |
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95 | c 1.1 Dust particles |
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96 | c ------------------ |
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97 | IF (doubleq.AND.active) THEN |
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98 | DO l=1,nlayer |
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99 | DO ig=1, ngrid |
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100 | call updaterdust(pq(ig,l,igcm_dust_mass), |
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101 | & pq(ig,l,igcm_dust_number),rdust(ig,l)) |
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102 | nueffdust(ig,l) = exp(varian**2.)-1. |
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103 | ENDDO |
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104 | ENDDO |
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105 | ELSE |
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106 | DO l=1,nlayer |
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107 | DO ig=1, ngrid |
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108 | rdust(ig,l) = 0.8E-6 |
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109 | nueffdust(ig,l) = 0.3 |
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110 | ENDDO |
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111 | ENDDO |
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112 | ENDIF |
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113 | |
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114 | ! updating radius of stormdust particles |
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115 | IF (rdstorm.AND.active) THEN |
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116 | DO l=1,nlayer |
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117 | DO ig=1, ngrid |
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118 | call updaterdust(pq(ig,l,igcm_stormdust_mass), |
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119 | & pq(ig,l,igcm_stormdust_number),rstormdust(ig,l)) |
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120 | nueffdust(ig,l) = exp(varian**2.)-1. |
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121 | ENDDO |
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122 | ENDDO |
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123 | ENDIF |
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124 | |
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125 | c 1.2 Water-ice particles |
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126 | c ----------------------- |
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127 | |
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128 | IF (water.AND.activice) THEN |
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129 | IF (microphys) THEN |
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130 | |
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131 | c At firstcall, the true number and true mass of cloud condensation nuclei are not known. |
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132 | c Indeed it is scaled on the prescribed dust opacity via a 'tauscaling' coefficient |
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133 | c computed after radiative transfer. If tauscaling is not in startfi, we make an assumption for its value. |
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134 | |
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135 | IF (firstcall) THEN |
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136 | !IF (minval(tauscaling).lt.0) tauscaling(:) = 1.e-3 ! default value when non-read in startfi is -1 |
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137 | !IF (freedust) tauscaling(:) = 1. ! if freedust, enforce no rescaling at all |
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138 | firstcall = .false. |
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139 | ENDIF |
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140 | |
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141 | DO l=1,nlayer |
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142 | DO ig=1,ngrid |
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143 | call updaterice_micro(pq(ig,l,igcm_h2o_ice), |
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144 | & pq(ig,l,igcm_ccn_mass), |
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145 | & pq(ig,l,igcm_ccn_number), |
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146 | & tauscaling(ig),rice(ig,l), |
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147 | & rhocloud(ig,l)) |
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148 | nuice(ig,l) = nuice_ref |
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149 | ENDDO |
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150 | ENDDO |
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151 | |
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152 | ELSE ! if not microphys |
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153 | |
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154 | DO l=1,nlayer |
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155 | DO ig=1,ngrid |
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156 | call updaterice_typ(pq(ig,l,igcm_h2o_ice), |
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157 | & tau(ig,1),pplay(ig,l),rice(ig,l)) |
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158 | nuice(ig,l) = nuice_ref |
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159 | ENDDO |
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160 | ENDDO |
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161 | |
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162 | ENDIF ! of if microphys |
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163 | ENDIF ! of if (water.AND.activice) |
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164 | |
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165 | c================================================================== |
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166 | c 2. Radius used in the radiative transfer code (reffrad) |
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167 | c================================================================== |
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168 | |
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169 | DO iaer = 1, naerkind ! Loop on aerosol kind |
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170 | aerkind: SELECT CASE (name_iaer(iaer)) |
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171 | c================================================================== |
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172 | CASE("dust_conrath") aerkind ! Typical dust profile |
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173 | c================================================================== |
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174 | DO l=1,nlayer |
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175 | DO ig=1,ngrid |
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176 | reffrad(ig,l,iaer) = rdust(ig,l) * |
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177 | & (1.e0 + nueffdust(ig,l))**2.5 |
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178 | nueffrad(ig,l,iaer) = nueffdust(ig,l) |
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179 | ENDDO |
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180 | ENDDO |
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181 | c================================================================== |
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182 | CASE("dust_doubleq") aerkind! Two-moment scheme for dust |
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183 | c================================================================== |
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184 | DO l=1,nlayer |
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185 | DO ig=1,ngrid |
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186 | reffrad(ig,l,iaer) = rdust(ig,l) * ref_r0 |
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187 | nueffrad(ig,l,iaer) = nueffdust(ig,l) |
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188 | ENDDO |
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189 | ENDDO |
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190 | c================================================================== |
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191 | CASE("dust_submicron") aerkind ! Small dust population |
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192 | c================================================================== |
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193 | DO l=1,nlayer |
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194 | DO ig=1,ngrid |
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195 | reffrad(ig,l,iaer)=radius(igcm_dust_submicron) |
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196 | nueffrad(ig,l,iaer)=0.03 |
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197 | ENDDO |
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198 | ENDDO |
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199 | c================================================================== |
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200 | CASE("h2o_ice") aerkind ! Water ice crystals |
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201 | c================================================================== |
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202 | DO l=1,nlayer |
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203 | DO ig=1,ngrid |
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204 | c About reffice, do not confuse the mass mean radius |
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205 | c (rayon moyen massique) and the number median radius |
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206 | c (or geometric mean radius, rayon moyen géométrique). |
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207 | c rice is a mass mean radius, whereas rdust |
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208 | c is a geometric mean radius: |
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209 | c number median rad = mass mean rad x exp(-1.5 sigma0^2) |
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210 | c (Montmessin et al. 2004 paragraph 30). Therefore: |
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211 | reffrad(ig,l,iaer)=rice(ig,l)*(1.+nuice_ref) |
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212 | nueffrad(ig,l,iaer)=nuice_ref |
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213 | ENDDO |
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214 | ENDDO |
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215 | c================================================================== |
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216 | CASE("stormdust_doubleq") aerkind! Two-moment scheme for |
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217 | c stormdust; same distribution than normal dust |
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218 | c================================================================== |
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219 | DO l=1,nlayer |
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220 | DO ig=1,ngrid |
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221 | reffrad(ig,l,iaer) = rstormdust(ig,l) * ref_r0 |
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222 | nueffrad(ig,l,iaer) = nueffdust(ig,l) |
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223 | ENDDO |
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224 | ENDDO |
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225 | c================================================================== |
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226 | END SELECT aerkind |
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227 | ENDDO ! iaer (loop on aerosol kind) |
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228 | |
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229 | END SUBROUTINE updatereffrad |
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230 | |
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231 | END MODULE updatereffrad_mod |
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