1 | subroutine SnOptP(jjtime) |
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2 | |
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3 | C +------------------------------------------------------------------------+ |
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4 | C | MAR/SISVAT SnOptP 12-08-2019 MAR | |
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5 | C | SubRoutine SnOptP computes the Snow Pack optical Properties | |
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6 | C +------------------------------------------------------------------------+ |
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7 | C | | |
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8 | C | PARAMETERS: knonv: Total Number of columns = | |
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9 | C | ^^^^^^^^^^ = Total Number of continental Grid Boxes | |
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10 | C | X Number of Mosaic Cell per Grid Box | |
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11 | C | | |
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12 | C | INPUT: isnoSV = total Nb of Ice/Snow Layers | |
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13 | C | ^^^^^ ispiSV = 0,...,nsno: Uppermost Superimposed Ice Layer | |
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14 | C | | |
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15 | C | | |
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16 | C | INPUT: G1snSV : Dendricity (<0) or Sphericity (>0) of Snow Layer | |
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17 | C | ^^^^^ G2snSV : Sphericity (>0) or Size of Snow Layer | |
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18 | C | agsnSV : Snow Age [day] | |
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19 | C | ro__SV : Snow/Soil Volumic Mass [kg/m3] | |
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20 | C | eta_SV : Water Content [m3/m3] | |
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21 | C | rusnSV : Surficial Water Thickness [kg/m2] .OR. [mm] | |
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22 | C | SWS_SV : Surficial Water Status | |
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23 | C | dzsnSV : Snow Layer Thickness [m] | |
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24 | C | | |
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25 | C | albssv : Soil Albedo [-] | |
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26 | C | zzsnsv : Snow Pack Thickness [m] | |
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27 | C | | |
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28 | C | OUTPUT: albisv : Snow/Ice/Water/Soil Integrated Albedo [-] | |
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29 | C | ^^^^^^ sEX_sv : Verticaly Integrated Extinction Coefficient | |
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30 | C | DOPsnSV : Snow Optical diameter [m] | |
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31 | C | | |
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32 | C | Internal Variables: | |
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33 | C | ^^^^^^^^^^^^^^^^^^ | |
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34 | C | SnOpSV : Snow Grain optical Size [m] | |
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35 | C | EX1_sv : Integrated Snow Extinction (0.3--0.8micr.m) | |
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36 | C | EX2_sv : Integrated Snow Extinction (0.8--1.5micr.m) | |
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37 | C | EX3_sv : Integrated Snow Extinction (1.5--2.8micr.m) | |
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38 | C | | |
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39 | C | METHODE: Calcul de la taille optique des grains ? partir de | |
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40 | C | ^^^^^^^ -leur type decrit par les deux variables descriptives | |
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41 | C | continues sur la plage -99/+99 passees en appel. | |
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42 | C | -la taille optique (1/10mm) des etoiles, | |
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43 | C | des grains fins et | |
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44 | C | des jeunes faces planes | |
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45 | C | | |
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46 | C | METHOD: Computation of the optical diameter of the grains | |
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47 | C | ^^^^^^ described with the CROCUS formalism G1snSV / G2snSV | |
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48 | C | | |
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49 | C | REFERENCE: Brun et al. 1989, J. Glaciol 35 pp. 333--342 | |
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50 | C | ^^^^^^^^^ Brun et al. 1992, J. Glaciol 38 pp. 13-- 22 | |
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51 | C | Eric Martin Sept.1996 | |
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52 | C | | |
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53 | C | | |
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54 | C +------------------------------------------------------------------------+ |
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55 | |
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56 | |
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57 | |
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58 | |
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59 | C +--Global Variables |
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60 | C + ================ |
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61 | |
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62 | |
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63 | use VARphy |
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64 | use VAR_SV |
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65 | use VARdSV |
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66 | use VARxSV |
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67 | use VARySV |
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68 | use VARtSV |
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69 | USE surface_data, only: iflag_albcalc,correc_alb |
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70 | |
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71 | IMPLICIT NONE |
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72 | |
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73 | |
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74 | C + -- INPUT |
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75 | integer jjtime |
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76 | |
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77 | C +--Internal Variables |
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78 | C + ================== |
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79 | |
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80 | real coalb1(knonv) ! weighted Coalbedo, Vis. |
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81 | real coalb2(knonv) ! weighted Coalbedo, nIR 1 |
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82 | real coalb3(knonv) ! weighted Coalbedo, nIR 2 |
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83 | real coalbm ! weighted Coalbedo, mean |
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84 | real sExt_1(knonv) ! Extinction Coeff., Vis. |
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85 | real sExt_2(knonv) ! Extinction Coeff., nIR 1 |
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86 | real sExt_3(knonv) ! Extinction Coeff., nIR 2 |
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87 | real SnOpSV(knonv, nsno) ! Snow Grain optical Size |
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88 | c #AG real agesno |
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89 | |
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90 | integer isn ,ikl ,isn1, i |
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91 | real sbeta1,sbeta2,sbeta3,sbeta4,sbeta5 |
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92 | real AgeMax,AlbMin,HSnoSV,HIceSV,doptmx,SignG1,Sph_OK |
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93 | real dalbed,dalbeS,dalbeW |
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94 | real bsegal,czemax,csegal,csza |
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95 | real RoFrez,DiffRo,SignRo,SnowOK,OpSqrt |
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96 | real albSn1,albIc1,a_SnI1,a_SII1 |
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97 | real albSn2,albIc2,a_SnI2,a_SII2 |
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98 | real albSn3,albIc3,a_SnI3,a_SII3 |
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99 | real albSno,albIce,albSnI,albSII,albWIc,albmax |
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100 | real doptic,Snow_H,SIce_H,SnownH,SIcenH |
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101 | real exarg1,exarg2,exarg3,sign_0,sExt_0 |
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102 | real albedo_old,albCor |
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103 | real ro_ave,dz_ave,minalb |
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104 | real l1min,l1max,l2min,l2max,l3min,l3max |
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105 | real l6min(6), l6max(6), albSn6(6), a_SII6(6) |
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106 | real lmintmp,lmaxtmp,albtmp |
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107 | |
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108 | C +--Local DATA |
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109 | C + ============ |
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110 | |
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111 | C +--For the computation of the solar irradiance extinction in snow |
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112 | C + ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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113 | data sbeta1/0.0192/,sbeta2/0.4000/,sbeta3/0.1098/ |
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114 | data sbeta4/1.0000/ |
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115 | data sbeta5/2.00e1/ |
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116 | |
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117 | C +--Snow Age Maximum (Taiga, e.g. Col de Porte) |
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118 | C + ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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119 | data AgeMax /60.0/ |
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120 | C +... AgeMax: Snow Age Maximum [day] |
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121 | |
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122 | data AlbMin /0.94/ |
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123 | C +... AlbMin: Albedo Minimum / visible (0.3--0.8 micrometers) |
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124 | |
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125 | data HSnoSV /0.01/ |
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126 | C +... HSnoSV: Snow Thickness through witch |
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127 | C + Albedo is interpolated to Ice Albedo |
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128 | data HIceSV /0.10/ |
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129 | C +... HIceSV: Snow/Ice Thickness through witch |
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130 | C + Albedo is interpolated to Soil Albedo |
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131 | data doptmx /2.3e-3/ |
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132 | C +... doptmx: Maximum optical Diameter (pi * R**2) [m] |
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133 | C + |
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134 | data czeMAX /0.173648178/ ! 80.deg (Segal et al., 1991 JAS) |
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135 | |
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136 | data bsegal /4.00 / ! |
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137 | data albmax /0.99 / ! Albedo max |
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138 | |
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139 | C +-- wavelength limits [m] for each broad band |
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140 | |
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141 | data l1min/400.0e-9/,l1max/800.0e-9/ |
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142 | data l2min/800.0e-9/,l2max/1500.0e-9/ |
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143 | data l3min/1500.0e-9/,l3max/2800.0e-9/ |
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144 | |
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145 | data l6min/185.0e-9,250.0e-9,400.0e-9, |
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146 | . 690.0e-9,1190.0e-9,2380.0e-9/ |
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147 | data l6max/250.0e-9,400.0e-9, |
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148 | . 690.0e-9,1190.0e-9,2380.0e-9,4000.0e-9/ |
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149 | |
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150 | |
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151 | C +--Snow Grain optical Size |
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152 | C + ======================= |
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153 | |
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154 | DO ikl=1,knonv |
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155 | DO isn=1,max(1,isnoSV(ikl)) |
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156 | |
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157 | G2snSV(ikl,isn) = max(epsi,G2snSV(ikl,isn)) |
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158 | C +... Avoid non physical Values |
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159 | |
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160 | SignG1 = sign(unun,G1snSV(ikl,isn)) |
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161 | Sph_OK = max(zero,SignG1) |
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162 | |
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163 | SnOpSV(ikl,isn) = 1.e-4 * |
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164 | C +... SI: (from 1/10 mm to m) |
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165 | |
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166 | |
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167 | C +--Contribution of Non Dendritic Snow |
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168 | C + ---------------------------------- |
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169 | |
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170 | . ( Sph_OK *( G2snSV(ikl,isn)*G1snSV(ikl,isn)/G1_dSV |
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171 | . +max(demi*G2snSV(ikl,isn),DFcdSV) |
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172 | . *(unun-G1snSV(ikl,isn) /G1_dSV)) |
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173 | |
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174 | |
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175 | C +--Contribution of Dendritic Snow |
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176 | C + ---------------------------------- |
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177 | |
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178 | . +(1.-Sph_OK)*( -G1snSV(ikl,isn)*DDcdSV /G1_dSV |
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179 | . +(unun+G1snSV(ikl,isn) /G1_dSV) |
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180 | . * (G2snSV(ikl,isn)*DScdSV /G1_dSV |
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181 | . +(unun-G2snSV(ikl,isn) /G1_dSV) |
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182 | . *DFcdSV ))) |
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183 | SnOpSV(ikl,isn) = max(zero,SnOpSV(ikl,isn)) |
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184 | |
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185 | C + --For outputs (Etienne) |
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186 | C + ------------------------ |
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187 | DOPsnSV(ikl,isn)=SnOpSV(ikl,isn) |
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188 | END DO |
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189 | END DO |
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190 | |
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191 | |
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192 | |
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193 | |
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194 | C +--Snow/Ice Albedo |
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195 | C + =============== |
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196 | |
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197 | |
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198 | |
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199 | C +--Uppermost effective Snow Layer |
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200 | C + ------------------------------ |
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201 | |
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202 | DO ikl=1,knonv |
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203 | |
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204 | isn = max(iun,isnoSV(ikl)) |
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205 | |
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206 | SignRo = sign(unun, rocdSV - ro__SV(ikl,isn)) |
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207 | SnowOK = max(zero,SignRo) ! Ice Density Threshold |
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208 | |
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209 | OpSqrt = sqrt(SnOpSV(ikl,isn)) |
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210 | |
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211 | cCA +--Correction of snow albedo for Antarctica/Greenland |
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212 | cCA -------------------------------------------------- |
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213 | |
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214 | |
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215 | albCor = correc_alb |
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216 | c #GL albCor = 1.01 |
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217 | c #AC albCor = 1.01 |
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218 | |
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219 | |
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220 | IF (iflag_albcalc .GE. 1) THEN ! Albedo calculation according to Kokhanovsky and Zege 2004 |
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221 | |
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222 | dalbed = 0.0 |
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223 | doptic=SnOpSV(ikl,isn) |
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224 | csza=coszSV(ikl) |
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225 | |
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226 | CALL albedo_kokhanovsky(l1min,l1max,csza,doptic,albSn1) |
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227 | CALL albedo_kokhanovsky(l2min,l2max,csza,doptic,albSn2) |
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228 | CALL albedo_kokhanovsky(l3min,l3max,csza,doptic,albSn3) |
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229 | |
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230 | DO i=1,6 |
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231 | lmintmp=l6min(i) |
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232 | lmaxtmp=l6max(i) |
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233 | CALL albedo_kokhanovsky(lmintmp,lmaxtmp,csza,doptic,albtmp) |
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234 | albSn6(i)=albtmp |
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235 | ENDDO |
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236 | |
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237 | |
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238 | ELSE ! Default calculation in SISVAT |
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239 | |
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240 | ! Zenith Angle Correction (Segal et al., 1991, JAS 48, p.1025) |
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241 | !--------------------------- (Wiscombe & Warren, dec1980, JAS , p.2723) |
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242 | ! (Warren, 1982, RG , p. 81) |
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243 | ! ------------------------------------------------- |
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244 | |
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245 | dalbed = 0.0 |
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246 | |
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247 | csegal = max(czemax ,coszSV(ikl)) |
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248 | c #cz dalbeS = ((bsegal+unun)/(unun+2.0*bsegal*csegal) |
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249 | c #cz. - unun )*0.32 |
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250 | c #cz. / bsegal |
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251 | c #cz dalbeS = max(dalbeS,zero) |
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252 | c #cz dalbed = dalbeS * min(1,isnoSV(ikl)) |
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253 | |
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254 | dalbeW =(0.64 - csegal )*0.0625 ! Warren 1982, RevGeo, fig.12b |
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255 | ! 0.0625 = 5% * 1/0.8, p.81 |
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256 | ! 0.64 = cos(50) |
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257 | dalbed = dalbeW * min(1,isnoSV(ikl)) |
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258 | !------------------------------------------------------------------------- |
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259 | |
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260 | albSn1 = 0.96-1.580*OpSqrt |
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261 | albSn1 = max(albSn1,AlbMin) |
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262 | |
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263 | albSn1 = max(albSn1,zero) |
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264 | albSn1 = min(albSn1*albCor,unun) |
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265 | |
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266 | albSn2 = 0.95-15.40*OpSqrt |
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267 | albSn2 = max(albSn2,zero) |
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268 | albSn2 = min(albSn2*albCor,unun) |
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269 | |
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270 | doptic = min(SnOpSV(ikl,isn),doptmx) |
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271 | albSn3 = 346.3*doptic -32.31*OpSqrt +0.88 |
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272 | albSn3 = max(albSn3,zero) |
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273 | albSn3 = min(albSn3*albCor,unun) |
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274 | |
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275 | albSn6(1:3)=albSn1 |
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276 | albSn6(4:6)=albSn2 |
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277 | |
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278 | !snow albedo corection if wetsnow |
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279 | c #GL albSn1 = albSn1*max(0.9,(1.-1.5*eta_SV(ikl,isn))) |
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280 | c #GL albSn2 = albSn2*max(0.9,(1.-1.5*eta_SV(ikl,isn))) |
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281 | c #GL albSn3 = albSn3*max(0.9,(1.-1.5*eta_SV(ikl,isn))) |
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282 | |
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283 | ENDIF |
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284 | |
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285 | |
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286 | albSno = So1dSV*albSn1 |
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287 | . + So2dSV*albSn2 |
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288 | . + So3dSV*albSn3 |
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289 | |
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290 | cXF |
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291 | minalb = (aI2dSV + (aI3dSV -aI2dSV) |
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292 | . * (ro__SV(ikl,isn)-ro_Ice)/(roSdSV-ro_Ice)) |
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293 | minalb = min(aI3dSV,max(aI2dSV,minalb)) ! pure/firn albedo |
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294 | |
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295 | SnowOK = SnowOK*max(zero,sign(unun, albSno-minalb)) |
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296 | albSn1 = SnowOK*albSn1+(1.0-SnowOK)*max(albSno,minalb) |
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297 | albSn2 = SnowOK*albSn2+(1.0-SnowOK)*max(albSno,minalb) |
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298 | albSn3 = SnowOK*albSn3+(1.0-SnowOK)*max(albSno,minalb) |
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299 | albSn6(:) = SnowOK*albSn6(:)+(1.0-SnowOK)*max(albSno,minalb) |
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300 | |
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301 | |
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302 | c + ro < roSdSV | min al > aI3dSV |
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303 | c + roSdSV < ro < rocdSV | aI2dSV < min al < aI3dSV (fct of density) |
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304 | |
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305 | |
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306 | C +--Snow/Ice Pack Thickness |
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307 | C + ----------------------- |
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308 | |
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309 | isn = max(min(isnoSV(ikl) ,ispiSV(ikl)),0) |
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310 | Snow_H = zzsnsv(ikl,isnoSV(ikl))-zzsnsv(ikl,isn) |
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311 | SIce_H = zzsnsv(ikl,isnoSV(ikl)) |
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312 | SnownH = Snow_H / HSnoSV |
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313 | SnownH = min(unun, SnownH) |
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314 | SIcenH = SIce_H / (HIceSV) |
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315 | SIcenH = min(unun, SIcenH) |
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316 | |
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317 | C + The value of SnownH is set to 1 in case of ice lenses above |
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318 | C + 1m of dry snow (ro<600kg/m3) for using CROCUS albedo |
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319 | |
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320 | c ro_ave = 0. |
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321 | c dz_ave = 0. |
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322 | c SnowOK = 1. |
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323 | c do isn = isnoSV(ikl),1,-1 |
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324 | c ro_ave = ro_ave + ro__SV(ikl,isn) * dzsnSV(ikl,isn) * SnowOK |
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325 | c dz_ave = dz_ave + dzsnSV(ikl,isn) * SnowOK |
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326 | c SnowOK = max(zero,sign(unun,1.-dz_ave)) |
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327 | c enddo |
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328 | |
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329 | c ro_ave = ro_ave / max(dz_ave,epsi) |
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330 | c SnowOK = max(zero,sign(unun,600.-ro_ave)) |
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331 | c SnownH = SnowOK + SnownH * (1. - SnowOK) |
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332 | |
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333 | C +--Integrated Snow/Ice Albedo: Case of Water on Bare Ice |
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334 | C + ----------------------------------------------------- |
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335 | |
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336 | isn = max(min(isnoSV(ikl) ,ispiSV(ikl)),0) |
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337 | |
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338 | albWIc = aI1dSV-(aI1dSV-aI2dSV) |
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339 | . * exp(-(rusnSV(ikl) ! |
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340 | . * (1. -SWS_SV(ikl) ! 0 <=> freezing |
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341 | . * (1 -min(1,iabs(isn-isnoSV(ikl))))) ! 1 <=> isn=isnoSV |
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342 | . / ru_dSV)**0.50) ! |
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343 | c albWIc = max(aI1dSV,min(aI2dSV,albWIc+slopSV(ikl)* |
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344 | c . min(5.,max(1.,dx/10000.)))) |
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345 | |
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346 | SignRo = sign(unun,ro_Ice-5.-ro__SV(ikl,isn)) ! RoSN<920kg/m3 |
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347 | SnowOK = max(zero,SignRo) |
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348 | |
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349 | albWIc = (1. - SnowOK) * albWIc + SnowOK |
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350 | . * (aI2dSV + (aI3dSV -aI2dSV) |
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351 | . * (ro__SV(ikl,isn)-ro_Ice)/(roSdSV-ro_Ice)) |
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352 | |
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353 | c + rocdSV < ro < ro_ice | aI2dSV< al <aI3dSV (fct of density) |
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354 | c + ro > ro_ice | aI1dSV< al <aI2dSV (fct of superficial water content |
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355 | |
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356 | |
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357 | C +--Integrated Snow/Ice Albedo |
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358 | C + ------------------------------- |
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359 | |
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360 | a_SII1 = albWIc +(albSn1-albWIc) *SnownH |
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361 | a_SII1 = min(a_SII1 ,albSn1) |
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362 | |
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363 | a_SII2 = albWIc +(albSn2-albWIc) *SnownH |
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364 | a_SII2 = min(a_SII2 ,albSn2) |
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365 | |
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366 | a_SII3 = albWIc +(albSn3-albWIc) *SnownH |
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367 | a_SII3 = min(a_SII3 ,albSn3) |
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368 | |
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369 | DO i=1,6 |
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370 | a_SII6(i) = albWIc +(albSn6(i)-albWIc) *SnownH |
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371 | a_SII6(i) = min(a_SII6(i) ,albSn6(i)) |
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372 | ENDDO |
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373 | |
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374 | cc #AG agesno = min(agsnSV(ikl,isn) ,AgeMax) |
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375 | cc #AG a_SII1 = a_SII1 -0.175*agesno/AgeMax |
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376 | C +... Impurities: Col de Porte Parameter. |
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377 | |
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378 | |
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379 | |
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380 | C +--Elsewhere Integrated Snow/Ice Albedo |
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381 | C + ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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382 | c #cp ELSE |
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383 | albSII = So1dSV*a_SII1 |
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384 | . + So2dSV*a_SII2 |
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385 | . + So3dSV*a_SII3 |
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386 | c #cp END IF |
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387 | |
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388 | |
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389 | C +--Integrated Snow/Ice/Soil Albedo |
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390 | C + ------------------------------- |
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391 | |
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392 | alb1sv(ikl) = albssv(ikl) +(a_SII1-albssv(ikl))*SIcenH |
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393 | alb1sv(ikl) = min(alb1sv(ikl) ,a_SII1) |
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394 | |
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395 | alb2sv(ikl) = albssv(ikl) +(a_SII2-albssv(ikl))*SIcenH |
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396 | alb2sv(ikl) = min(alb2sv(ikl) ,a_SII2) |
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397 | |
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398 | alb3sv(ikl) = albssv(ikl) +(a_SII3-albssv(ikl))*SIcenH |
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399 | alb3sv(ikl) = min(alb3sv(ikl) ,a_SII3) |
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400 | |
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401 | albisv(ikl) = albssv(ikl) +(albSII-albssv(ikl))*SIcenH |
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402 | albisv(ikl) = min(albisv(ikl) ,albSII) |
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403 | |
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404 | DO i=1,6 |
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405 | alb6sv(ikl,i) = albssv(ikl) +(a_SII6(i)-albssv(ikl))*SIcenH |
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406 | alb6sv(ikl,i) = min(alb6sv(ikl,i) ,a_SII6(i)) |
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407 | ENDDO |
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408 | |
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409 | |
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410 | C +--Integrated Snow/Ice/Soil Albedo: Clouds Correction! Greuell & all., 1994 |
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411 | C + --------------------------------------------------! Glob.&t Planet.Change |
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412 | ! (9):91-114 |
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413 | alb1sv(ikl) = alb1sv(ikl) + 0.05 *(cld_SV(ikl)-0.5)*SIcenH |
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414 | . + dalbed * (1.-cld_SV(ikl)) |
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415 | alb2sv(ikl) = alb2sv(ikl) + 0.05 *(cld_SV(ikl)-0.5)*SIcenH |
---|
416 | . + dalbed * (1.-cld_SV(ikl)) |
---|
417 | alb3sv(ikl) = alb3sv(ikl) + 0.05 *(cld_SV(ikl)-0.5)*SIcenH |
---|
418 | . + dalbed * (1.-cld_SV(ikl)) |
---|
419 | alb6sv(ikl,:) =alb6sv(ikl,:)+0.05 *(cld_SV(ikl)-0.5)*SIcenH |
---|
420 | . + dalbed * (1.-cld_SV(ikl)) |
---|
421 | albisv(ikl) = albisv(ikl) + 0.05 *(cld_SV(ikl)-0.5)*SIcenH |
---|
422 | . + dalbed * (1.-cld_SV(ikl)) |
---|
423 | |
---|
424 | C +--Integrated Snow/Ice/Soil Albedo: Minimum snow albedo = aI1dSV |
---|
425 | C + ------------------------------------------------------------- |
---|
426 | |
---|
427 | albedo_old = albisv(ikl) |
---|
428 | albisv(ikl) = max(albisv(ikl),aI1dSV * SIcenH |
---|
429 | . + albssv(ikl) *(1.0 - SIcenH)) |
---|
430 | alb1sv(ikl) = alb1sv(ikl) - 1.0/3.0 ! 33 % |
---|
431 | . * (albedo_old-albisv(ikl)) / So1dSV |
---|
432 | alb2sv(ikl) = alb2sv(ikl) - 1.0/3.0 ! 33 % |
---|
433 | . * (albedo_old-albisv(ikl)) / So2dSV |
---|
434 | alb3sv(ikl) = alb3sv(ikl) - 1.0/3.0 ! 33 % |
---|
435 | . * (albedo_old-albisv(ikl)) / So3dSV |
---|
436 | alb6sv(ikl,1:3) = alb6sv(ikl,1:3) - 1.0/6.0 ! 16 % |
---|
437 | . * (albedo_old-albisv(ikl)) / (So1dSV/3) |
---|
438 | alb6sv(ikl,4:6) = alb6sv(ikl,4:6) - 1.0/6.0 ! 16 % |
---|
439 | . * (albedo_old-albisv(ikl)) / (So2dSV/3) |
---|
440 | |
---|
441 | |
---|
442 | C +--Integrated Snow/Ice/Soil Albedo: Maximum albedo = 95% |
---|
443 | C + ----------------------------------------------------- |
---|
444 | |
---|
445 | albedo_old = albisv(ikl) |
---|
446 | albisv(ikl) = min(albisv(ikl),0.95) |
---|
447 | alb1sv(ikl) = alb1sv(ikl) - 1.0/3.0 ! 33 % |
---|
448 | . * (albedo_old-albisv(ikl)) / So1dSV |
---|
449 | alb2sv(ikl) = alb2sv(ikl) - 1.0/3.0 ! 33 % |
---|
450 | . * (albedo_old-albisv(ikl)) / So2dSV |
---|
451 | alb3sv(ikl) = alb3sv(ikl) - 1.0/3.0 ! 33 % |
---|
452 | . * (albedo_old-albisv(ikl)) / So3dSV |
---|
453 | alb6sv(ikl,1:3) = alb6sv(ikl,1:3) - 1.0/6.0 ! 16 % |
---|
454 | . * (albedo_old-albisv(ikl)) / (So1dSV/3) |
---|
455 | alb6sv(ikl,4:6) = alb6sv(ikl,4:6) - 1.0/6.0 ! 16 % |
---|
456 | . * (albedo_old-albisv(ikl)) / (So2dSV/3) |
---|
457 | |
---|
458 | |
---|
459 | !Sea Ice/snow permanent-interractive prescription from Nemo |
---|
460 | !AO_CK 20/02/2020 |
---|
461 | |
---|
462 | ! No check if coupling update since MAR and NEMO albedo are too different |
---|
463 | ! and since MAR albedo is computed on properties that are not in NEMO |
---|
464 | ! prescription for each time step with NEMO values |
---|
465 | |
---|
466 | c #AO if (LSmask(ikl) .eq. 0 .and. coupling_ao .eq. .true.) then |
---|
467 | c #AO if (AOmask(ikl) .eq. 0) then |
---|
468 | c #AO albisv(ikl) = (1.-AOmask(ikl))* albAOsisv(ikl) |
---|
469 | c #AO. +(AOmask(ikl)*albisv(ikl)) |
---|
470 | c #AO alb1sv(ikl) = (1.-AOmask(ikl))* albAOsisv(ikl) |
---|
471 | c #AO. +(AOmask(ikl)*alb1sv(ikl)) |
---|
472 | c #AO alb2sv(ikl) = (1.-AOmask(ikl))* albAOsisv(ikl) |
---|
473 | c #AO. +(AOmask(ikl)*alb2sv(ikl)) |
---|
474 | c #AO alb3sv(ikl) = (1.-AOmask(ikl))* albAOsisv(ikl) |
---|
475 | c #AO. +(AOmask(ikl)*alb3sv(ikl)) |
---|
476 | c #AO endif |
---|
477 | c #AO endif |
---|
478 | |
---|
479 | |
---|
480 | alb1sv(ikl) = min(max(zero,alb1sv(ikl)),albmax) |
---|
481 | alb2sv(ikl) = min(max(zero,alb2sv(ikl)),albmax) |
---|
482 | alb3sv(ikl) = min(max(zero,alb3sv(ikl)),albmax) |
---|
483 | |
---|
484 | DO i=1,6 |
---|
485 | alb6sv(ikl,i) = min(max(zero,alb6sv(ikl,i)),albmax) |
---|
486 | ENDDO |
---|
487 | END DO |
---|
488 | |
---|
489 | |
---|
490 | C +--Extinction Coefficient: Exponential Factor |
---|
491 | C + ========================================== |
---|
492 | |
---|
493 | DO ikl=1,knonv |
---|
494 | sExt_1(ikl) = 1. |
---|
495 | sExt_2(ikl) = 1. |
---|
496 | sExt_3(ikl) = 1. |
---|
497 | sEX_sv(ikl,nsno+1) = 1. |
---|
498 | |
---|
499 | coalb1(ikl) = (1. -alb1sv(ikl))*So1dSV |
---|
500 | coalb2(ikl) = (1. -alb2sv(ikl))*So2dSV |
---|
501 | coalb3(ikl) = (1. -alb3sv(ikl))*So3dSV |
---|
502 | coalbm = coalb1(ikl) +coalb2(ikl) +coalb3(ikl) |
---|
503 | coalb1(ikl) = coalb1(ikl) /coalbm |
---|
504 | coalb2(ikl) = coalb2(ikl) /coalbm |
---|
505 | coalb3(ikl) = coalb3(ikl) /coalbm |
---|
506 | END DO |
---|
507 | |
---|
508 | cXF |
---|
509 | |
---|
510 | DO isn=nsno,1,-1 |
---|
511 | DO ikl=1,knonv |
---|
512 | sEX_sv(ikl,isn) = 1.0 |
---|
513 | !sEX_sv(ikl,isn) = 0.95 ! if MAR is too warm in summer |
---|
514 | END DO |
---|
515 | END DO |
---|
516 | |
---|
517 | DO ikl=1,knonv |
---|
518 | DO isn=max(1,isnoSV(ikl)),1,-1 |
---|
519 | |
---|
520 | SignRo = sign(unun, rocdSV - ro__SV(ikl,isn)) |
---|
521 | SnowOK = max(zero,SignRo) ! Ice Density Threshold |
---|
522 | |
---|
523 | RoFrez = 1.e-3 * ro__SV(ikl,isn) * (1.0-eta_SV(ikl,isn)) |
---|
524 | |
---|
525 | OpSqrt = sqrt(max(epsi,SnOpSV(ikl,isn))) |
---|
526 | exarg1 = SnowOK *1.e2 *max(sbeta1*RoFrez/OpSqrt,sbeta2) |
---|
527 | . +(1.0-SnowOK) *sbeta5 |
---|
528 | exarg2 = SnowOK *1.e2 *max(sbeta3*RoFrez/OpSqrt,sbeta4) |
---|
529 | . +(1.0-SnowOK) *sbeta5 |
---|
530 | exarg3 = SnowOK *1.e2 *sbeta5 |
---|
531 | . +(1.0-SnowOK) *sbeta5 |
---|
532 | |
---|
533 | |
---|
534 | C +--Integrated Extinction of Solar Irradiance (Normalized Value) |
---|
535 | C + ============================================================ |
---|
536 | |
---|
537 | sExt_1(ikl) = sExt_1(ikl) |
---|
538 | . * exp(min(0.0,-exarg1 *dzsnSV(ikl,isn))) |
---|
539 | sign_0 = sign(unun,eps9 -sExt_1(ikl)) |
---|
540 | sExt_0 = max(zero,sign_0)*sExt_1(ikl) |
---|
541 | sExt_1(ikl) = sExt_1(ikl) -sExt_0 |
---|
542 | |
---|
543 | sExt_2(ikl) = sExt_2(ikl) |
---|
544 | . * exp(min(0.0,-exarg2 *dzsnSV(ikl,isn))) |
---|
545 | sign_0 = sign(unun,eps9 -sExt_2(ikl)) |
---|
546 | sExt_0 = max(zero,sign_0)*sExt_2(ikl) |
---|
547 | sExt_2(ikl) = sExt_2(ikl) -sExt_0 |
---|
548 | |
---|
549 | sExt_3(ikl) = sExt_3(ikl) |
---|
550 | . * exp(min(0.0,-exarg3 *dzsnSV(ikl,isn))) |
---|
551 | sign_0 = sign(unun,eps9 -sExt_3(ikl)) |
---|
552 | sExt_0 = max(zero,sign_0)*sExt_3(ikl) |
---|
553 | sExt_3(ikl) = sExt_3(ikl) -sExt_0 |
---|
554 | |
---|
555 | sEX_sv(ikl,isn) = coalb1(ikl) * sExt_1(ikl) |
---|
556 | . + coalb2(ikl) * sExt_2(ikl) |
---|
557 | . + coalb3(ikl) * sExt_3(ikl) |
---|
558 | END DO |
---|
559 | END DO |
---|
560 | |
---|
561 | DO isn=0,-nsol,-1 |
---|
562 | DO ikl=1,knonv |
---|
563 | sEX_sv(ikl,isn) = 0.0 |
---|
564 | END DO |
---|
565 | END DO |
---|
566 | |
---|
567 | |
---|
568 | return |
---|
569 | |
---|
570 | |
---|
571 | end |
---|
572 | |
---|
573 | |
---|
574 | !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ |
---|
575 | SUBROUTINE albedo_kokhanovsky(lambdamin,lambdamax, |
---|
576 | . cossza,dopt,albint) |
---|
577 | !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ |
---|
578 | ! Authors: Hajar El Habchi El Fenniri, Etienne Vignon, Cecile Agosta |
---|
579 | ! Ghislain Picard |
---|
580 | ! Routine that calculates the integrated snow spectral albedo between |
---|
581 | ! lambdamin and lambdamax following Kokhanisky and Zege 2004, |
---|
582 | ! Scattering optics of snow, Applied Optics, Vol 43, No7 |
---|
583 | ! Code inspired from the snowoptics package of Ghislain Picard: |
---|
584 | ! https://github.com/ghislainp/snowoptics |
---|
585 | !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ |
---|
586 | |
---|
587 | |
---|
588 | USE VARphy |
---|
589 | |
---|
590 | IMPLICIT NONE |
---|
591 | |
---|
592 | ! Inputs |
---|
593 | !-------- |
---|
594 | REAL lambdamin ! minimum wavelength for integration [m] |
---|
595 | REAL lambdamax ! maximum wavelength for integration [m] |
---|
596 | REAL cossza ! solar zenith angle cosinus |
---|
597 | REAL dopt ! optical diameter [m] |
---|
598 | |
---|
599 | !Outputs |
---|
600 | !------- |
---|
601 | REAL albint |
---|
602 | |
---|
603 | ! Local Variables |
---|
604 | !----------------- |
---|
605 | |
---|
606 | REAL ropt,cosalb,norm,Pas |
---|
607 | REAL SSA,alpha,gamm,R,cos30,alb30 |
---|
608 | INTEGER i |
---|
609 | |
---|
610 | |
---|
611 | REAL B_amp ! amplification factor |
---|
612 | PARAMETER (B_amp=1.6) |
---|
613 | |
---|
614 | REAL g_asy ! asymetry factor |
---|
615 | PARAMETER (g_asy=0.845) |
---|
616 | |
---|
617 | INTEGER nlambda ! length of wavelength vector |
---|
618 | PARAMETER(nlambda=200) |
---|
619 | |
---|
620 | REAL lmin |
---|
621 | PARAMETER(lmin=185.0E-9) |
---|
622 | |
---|
623 | REAL lmax |
---|
624 | PARAMETER(lmax=4000.0E-9) |
---|
625 | |
---|
626 | REAL albmax |
---|
627 | PARAMETER(albmax=0.99) |
---|
628 | |
---|
629 | REAL wavelengths(nlambda) |
---|
630 | REAL ni(nlambda) |
---|
631 | |
---|
632 | DATA wavelengths / 1.85000000e-07, 2.04170854e-07, |
---|
633 | . 2.23341709e-07, 2.42512563e-07, |
---|
634 | . 2.61683417e-07, 2.80854271e-07, 3.00025126e-07, 3.19195980e-07, |
---|
635 | . 3.38366834e-07, 3.57537688e-07, 3.76708543e-07, 3.95879397e-07, |
---|
636 | . 4.15050251e-07, 4.34221106e-07, 4.53391960e-07, 4.72562814e-07, |
---|
637 | . 4.91733668e-07, 5.10904523e-07, 5.30075377e-07, 5.49246231e-07, |
---|
638 | . 5.68417085e-07, 5.87587940e-07, 6.06758794e-07, 6.25929648e-07, |
---|
639 | . 6.45100503e-07, 6.64271357e-07, 6.83442211e-07, 7.02613065e-07, |
---|
640 | . 7.21783920e-07, 7.40954774e-07, 7.60125628e-07, 7.79296482e-07, |
---|
641 | . 7.98467337e-07, 8.17638191e-07, 8.36809045e-07, 8.55979899e-07, |
---|
642 | . 8.75150754e-07, 8.94321608e-07, 9.13492462e-07, 9.32663317e-07, |
---|
643 | . 9.51834171e-07, 9.71005025e-07, 9.90175879e-07, 1.00934673e-06, |
---|
644 | . 1.02851759e-06, 1.04768844e-06, 1.06685930e-06, 1.08603015e-06, |
---|
645 | . 1.10520101e-06, 1.12437186e-06, 1.14354271e-06, 1.16271357e-06, |
---|
646 | . 1.18188442e-06, 1.20105528e-06, 1.22022613e-06, 1.23939698e-06, |
---|
647 | . 1.25856784e-06, 1.27773869e-06, 1.29690955e-06, 1.31608040e-06, |
---|
648 | . 1.33525126e-06, 1.35442211e-06, 1.37359296e-06, 1.39276382e-06, |
---|
649 | . 1.41193467e-06, 1.43110553e-06, 1.45027638e-06, 1.46944724e-06, |
---|
650 | . 1.48861809e-06, 1.50778894e-06, 1.52695980e-06, 1.54613065e-06, |
---|
651 | . 1.56530151e-06, 1.58447236e-06, 1.60364322e-06, 1.62281407e-06, |
---|
652 | . 1.64198492e-06, 1.66115578e-06, 1.68032663e-06, 1.69949749e-06, |
---|
653 | . 1.71866834e-06, 1.73783920e-06, 1.75701005e-06, 1.77618090e-06, |
---|
654 | . 1.79535176e-06, 1.81452261e-06, 1.83369347e-06, 1.85286432e-06, |
---|
655 | . 1.87203518e-06, 1.89120603e-06, 1.91037688e-06, 1.92954774e-06, |
---|
656 | . 1.94871859e-06, 1.96788945e-06, 1.98706030e-06, 2.00623116e-06, |
---|
657 | . 2.02540201e-06, 2.04457286e-06, 2.06374372e-06, 2.08291457e-06, |
---|
658 | . 2.10208543e-06, 2.12125628e-06, 2.14042714e-06, 2.15959799e-06, |
---|
659 | . 2.17876884e-06, 2.19793970e-06, 2.21711055e-06, 2.23628141e-06, |
---|
660 | . 2.25545226e-06, 2.27462312e-06, 2.29379397e-06, 2.31296482e-06, |
---|
661 | . 2.33213568e-06, 2.35130653e-06, 2.37047739e-06, 2.38964824e-06, |
---|
662 | . 2.40881910e-06, 2.42798995e-06, 2.44716080e-06, 2.46633166e-06, |
---|
663 | . 2.48550251e-06, 2.50467337e-06, 2.52384422e-06, 2.54301508e-06, |
---|
664 | . 2.56218593e-06, 2.58135678e-06, 2.60052764e-06, 2.61969849e-06, |
---|
665 | . 2.63886935e-06, 2.65804020e-06, 2.67721106e-06, 2.69638191e-06, |
---|
666 | . 2.71555276e-06, 2.73472362e-06, 2.75389447e-06, 2.77306533e-06, |
---|
667 | . 2.79223618e-06, 2.81140704e-06, 2.83057789e-06, 2.84974874e-06, |
---|
668 | . 2.86891960e-06, 2.88809045e-06, 2.90726131e-06, 2.92643216e-06, |
---|
669 | . 2.94560302e-06, 2.96477387e-06, 2.98394472e-06, 3.00311558e-06, |
---|
670 | . 3.02228643e-06, 3.04145729e-06, 3.06062814e-06, 3.07979899e-06, |
---|
671 | . 3.09896985e-06, 3.11814070e-06, 3.13731156e-06, 3.15648241e-06, |
---|
672 | . 3.17565327e-06, 3.19482412e-06, 3.21399497e-06, 3.23316583e-06, |
---|
673 | . 3.25233668e-06, 3.27150754e-06, 3.29067839e-06, 3.30984925e-06, |
---|
674 | . 3.32902010e-06, 3.34819095e-06, 3.36736181e-06, 3.38653266e-06, |
---|
675 | . 3.40570352e-06, 3.42487437e-06, 3.44404523e-06, 3.46321608e-06, |
---|
676 | . 3.48238693e-06, 3.50155779e-06, 3.52072864e-06, 3.53989950e-06, |
---|
677 | . 3.55907035e-06, 3.57824121e-06, 3.59741206e-06, 3.61658291e-06, |
---|
678 | . 3.63575377e-06, 3.65492462e-06, 3.67409548e-06, 3.69326633e-06, |
---|
679 | . 3.71243719e-06, 3.73160804e-06, 3.75077889e-06, 3.76994975e-06, |
---|
680 | . 3.78912060e-06, 3.80829146e-06, 3.82746231e-06, 3.84663317e-06, |
---|
681 | . 3.86580402e-06, 3.88497487e-06, 3.90414573e-06, 3.92331658e-06, |
---|
682 | . 3.94248744e-06, 3.96165829e-06, 3.98082915e-06, 4.00000000e-06/ |
---|
683 | |
---|
684 | |
---|
685 | DATA ni /7.74508407e-10, 7.74508407e-10, |
---|
686 | . 7.74508407e-10, 7.74508407e-10, |
---|
687 | . 7.74508407e-10, 7.74508407e-10, 7.74508407e-10, 7.74508407e-10, |
---|
688 | . 6.98381122e-10, 6.23170274e-10, 5.97655992e-10, 5.84106004e-10, |
---|
689 | . 5.44327597e-10, 5.71923510e-10, 6.59723827e-10, 8.05183870e-10, |
---|
690 | . 1.03110161e-09, 1.36680386e-09, 1.85161253e-09, 2.56487751e-09, |
---|
691 | . 3.56462855e-09, 4.89450926e-09, 6.49252022e-09, 9.62029335e-09, |
---|
692 | . 1.32335015e-08, 1.75502184e-08, 2.19240625e-08, 3.03304156e-08, |
---|
693 | . 4.07715972e-08, 5.00414911e-08, 7.09722331e-08, 1.00773751e-07, |
---|
694 | . 1.31427409e-07, 1.42289041e-07, 1.49066787e-07, 2.01558515e-07, |
---|
695 | . 2.99106105e-07, 4.03902086e-07, 4.54292169e-07, 5.21906983e-07, |
---|
696 | . 6.27643362e-07, 9.43955678e-07, 1.33464494e-06, 1.97278315e-06, |
---|
697 | . 2.31801329e-06, 2.20584676e-06, 1.85568138e-06, 1.73395193e-06, |
---|
698 | . 1.73101406e-06, 1.91333936e-06, 2.26413019e-06, 3.23959718e-06, |
---|
699 | . 4.94316963e-06, 6.89378896e-06, 1.02237444e-05, 1.21439656e-05, |
---|
700 | . 1.31567585e-05, 1.33448288e-05, 1.32000000e-05, 1.31608040e-05, |
---|
701 | . 1.33048369e-05, 1.40321464e-05, 1.51526244e-05, 1.80342858e-05, |
---|
702 | . 3.82875736e-05, 1.07325259e-04, 2.11961637e-04, 3.82008054e-04, |
---|
703 | . 5.30897470e-04, 5.29244735e-04, 4.90876605e-04, 4.33905427e-04, |
---|
704 | . 3.77795349e-04, 3.17633099e-04, 2.81078564e-04, 2.57579485e-04, |
---|
705 | . 2.42203100e-04, 2.23789060e-04, 2.04306870e-04, 1.87909255e-04, |
---|
706 | . 1.73117146e-04, 1.61533186e-04, 1.53420328e-04, 1.47578033e-04, |
---|
707 | . 1.42334776e-04, 1.35691466e-04, 1.30495414e-04, 1.36065123e-04, |
---|
708 | . 1.70928821e-04, 2.66389730e-04, 4.80957955e-04, 8.25041961e-04, |
---|
709 | . 1.21654792e-03, 1.50232875e-03, 1.62316078e-03, 1.61649750e-03, |
---|
710 | . 1.53736801e-03, 1.42343711e-03, 1.24459117e-03, 1.02388611e-03, |
---|
711 | . 7.89112523e-04, 5.97204264e-04, 4.57152413e-04, 3.62341259e-04, |
---|
712 | . 2.99128332e-04, 2.57035569e-04, 2.26992203e-04, 2.07110355e-04, |
---|
713 | . 2.05835688e-04, 2.25108810e-04, 2.64262893e-04, 3.23594011e-04, |
---|
714 | . 3.93061117e-04, 4.62789970e-04, 5.19664416e-04, 5.59739628e-04, |
---|
715 | . 5.93476084e-04, 6.22797885e-04, 6.57484833e-04, 6.92849600e-04, |
---|
716 | . 7.26584901e-04, 7.56604648e-04, 7.68009488e-04, 7.65579073e-04, |
---|
717 | . 7.50526164e-04, 7.39809972e-04, 7.55622847e-04, 8.05099514e-04, |
---|
718 | . 9.67279246e-04, 1.16281559e-03, 1.42570247e-03, 2.04986585e-03, |
---|
719 | . 2.93971170e-03, 4.49827711e-03, 7.32537532e-03, 1.18889734e-02, |
---|
720 | . 1.85851805e-02, 2.86242532e-02, 4.34131035e-02, 6.37828307e-02, |
---|
721 | . 9.24145850e-02, 1.35547945e-01, 1.94143245e-01, 2.54542814e-01, |
---|
722 | . 3.02282024e-01, 3.42214181e-01, 3.85475065e-01, 4.38000000e-01, |
---|
723 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
724 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
725 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
726 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
727 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
728 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
729 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
730 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
731 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
732 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
733 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
734 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, |
---|
735 | . 4.38000000e-01, 4.38000000e-01, 4.38000000e-01, 4.38000000e-01/ |
---|
736 | |
---|
737 | |
---|
738 | Pas =(lmax-lmin)/nlambda |
---|
739 | ropt = dopt/2.0 |
---|
740 | SSA = 3.0/(rhoIce*ropt) |
---|
741 | cos30 = cos(30.0/180.0*pi) |
---|
742 | |
---|
743 | |
---|
744 | albint=0. |
---|
745 | norm=0. |
---|
746 | |
---|
747 | DO i = 1,nlambda |
---|
748 | gamm = 4.0 * pi * ni(i) / wavelengths(i) |
---|
749 | cosalb = 2.0 / (SSA * rhoice) * B_amp * gamm |
---|
750 | alpha = 16. / 3 * cosalb / (1.0 - g_asy) |
---|
751 | R = exp(-(alpha**0.5) * 3.0 / 7.0 * (1.0 + 2.0 * cossza)) |
---|
752 | alb30 = exp(-(alpha**0.5)* 3.0 / 7.0 * (1.0 + 20 * cos30)) |
---|
753 | |
---|
754 | IF ((wavelengths(i).GE.lambdamin).AND. |
---|
755 | . (wavelengths(i).LT.lambdamax)) THEN |
---|
756 | albint=albint+R*Pas ! rectangle integration -> can be improved with trapezintegration |
---|
757 | norm=norm+Pas |
---|
758 | ENDIF |
---|
759 | |
---|
760 | END DO |
---|
761 | |
---|
762 | albint=max(0.,min(albint/max(norm,1E-10),albmax)) |
---|
763 | |
---|
764 | END |
---|
765 | |
---|