1 | ##General options |
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2 | ##~~~~~~~~~~~~~~~ |
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3 | #Run with or without tracer transport ? |
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4 | tracer=.true. |
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5 | |
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6 | #Directory where external input files are: |
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7 | datadir=./data_physics/ |
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8 | |
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9 | #Diurnal cycle ? if diurnal=False, diurnal averaged solar heating |
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10 | diurnal=.true. |
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11 | |
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12 | #Seasonal cycle ? if season=False, Ls stays constant, to value set in "start" |
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13 | season = .true. |
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14 | |
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15 | #write some more output on the screen ? |
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16 | lwrite = .false. |
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17 | |
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18 | #Save statistics in file "stats.nc" ? |
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19 | callstats =.true. |
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20 | |
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21 | #Save EOF profiles in file "profiles" for Climate Database? |
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22 | calleofdump = .false. |
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23 | |
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24 | ## Dust scenario. Used if the dust is prescribed (i.e. if tracer=F or active=F) |
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25 | ## ~~~~~~~~~~~~~ |
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26 | # =1 Dust opt.deph read in startfi; =2 Viking scenario; =3 MGS scenario, |
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27 | # =4 Mars Year 24 from TES assimilation (old version of MY24; dust_tes.nc file) |
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28 | # =6 "cold" (low dust) scenario ; =7 "warm" (high dust) scenario |
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29 | # =8 "climatology" (our best guess of a typical Mars year) scenario |
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30 | # =24 Mars Year 24 ; =25 Mars Year 25 (year with a global dust storm) ; ... |
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31 | # =30 Mars Year 30 |
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32 | iaervar = 34 |
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33 | # Dust opacity at 610 Pa (when constant, i.e. for the iaervar=1 case) |
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34 | tauvis=0.1 |
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35 | # Dust vertical distribution: |
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36 | # (=0: old distrib. (Pollack90), =1: top set by "topdustref", |
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37 | # =2: Viking scenario; =3 MGS scenario) |
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38 | iddist = 3 |
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39 | # Dust top altitude (km). (Matters only if iddist=1) |
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40 | topdustref = 55. |
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41 | |
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42 | ## Physical Parameterizations : |
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43 | ## ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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44 | # call radiative transfer ? |
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45 | callrad = .true. |
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46 | # call NLTE radiative schemes ? matters only if callrad=T |
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47 | callnlte = .true. |
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48 | #callnlte = .false. |
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49 | # NLTE 15um scheme to use. |
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50 | # 0-> Old scheme, static oxygen |
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51 | # 1-> Old scheme, dynamic oxygen |
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52 | # 2-> New scheme |
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53 | nltemodel = 2 |
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54 | nltemodel = 0 |
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55 | # call CO2 NIR absorption ? matters only if callrad=T |
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56 | callnirco2 = .true. |
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57 | # NIR NLTE correction ? matters only if callnirco2=T |
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58 | nircorr=1 |
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59 | nircorr=0 |
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60 | # call turbulent vertical diffusion ? |
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61 | calldifv = .true. |
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62 | # call convective adjustment ? |
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63 | calladj = .true. |
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64 | # Thermals |
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65 | calltherm = .true. |
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66 | callrichsl = .true. |
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67 | # call CO2 condensation ? |
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68 | callcond =.true. |
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69 | # call thermal conduction in the soil ? |
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70 | callsoil = .true. |
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71 | # call Lott's gravity wave/subgrid topography scheme ? |
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72 | calllott = .true. |
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73 | # Impose polar cap surface albedos as observed by TES? |
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74 | TESicealbedo = .true. |
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75 | ## Coefficient for Northern cap albedoes |
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76 | TESice_Ncoef=1.6 |
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77 | ## Coefficient for Southern cap albedoes |
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78 | TESice_Scoef=1.6 |
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79 | |
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80 | |
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81 | ## Radiative transfer options : |
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82 | ## ~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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83 | # the rad.transfer is computed every "iradia" physical timestep |
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84 | iradia = 1 |
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85 | # Output of the exchange coefficient mattrix ? for diagnostic only |
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86 | callg2d = .false. |
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87 | # Rayleigh scattering : (should be .false. for now) |
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88 | rayleigh = .false. |
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89 | |
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90 | ## Tracer (dust water, ice and/or chemical species) options (used if tracer=T): |
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91 | ## ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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92 | # DUST: Transported dust ? (if >0, use 'dustbin' dust bins) |
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93 | dustbin = 2 |
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94 | # DUST: Radiatively active dust ? (matters if dustbin>0) |
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95 | active = .true. |
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96 | # DUST: use mass and number mixing ratios to predict dust size ? |
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97 | doubleq = .true. |
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98 | # DUST: lifted by GCM surface winds ? |
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99 | lifting = .true. |
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100 | # DUST: lifted by dust devils ? |
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101 | callddevil = .false. |
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102 | # DUST: Scavenging by H2O/CO2 snowfall ? |
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103 | scavenging = .true. |
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104 | # DUST/WATERICE: Gravitationnal sedimentation ? |
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105 | sedimentation = .true. |
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106 | # WATERICE: Radiatively active transported atmospheric water ice ? |
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107 | activice = .true. |
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108 | # WATER: Compute water cycle |
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109 | water = .true. |
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110 | # WATER: Microphysical scheme for water-ice clouds? |
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111 | microphys = .true. |
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112 | ## WATER: microphysics sub-timestep |
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113 | #imicro = 15 |
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114 | # WATER: parameter contact |
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115 | mteta = 0.95 |
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116 | # WATER: Effective variance for sedimentation for the log-normal |
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117 | # distribution of ice particles ? |
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118 | nuice_sed=0.1 |
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119 | # WATER: current permanent caps at both poles. True IS RECOMMENDED |
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120 | # (with .true., North cap is a source of water and South pole |
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121 | # is a cold trap) |
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122 | caps = .true. |
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123 | # WATER: Water ice albedo ? |
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124 | albedo_h2o_ice = 0.35 |
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125 | # WATER: Water ice thermal inertia |
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126 | inert_h2o_ice = 800 |
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127 | # WATER: Frost thickness threshold for albedo |
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128 | frost_albedo_threshold = 0.005 |
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129 | # PHOTOCHEMISTRY: include chemical species |
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130 | photochem = .true. |
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131 | photochem = .false. |
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132 | |
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133 | # SCATTERERS: set number of scatterers. must be compliant with preceding options. |
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134 | naerkind = 2 |
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135 | |
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136 | |
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137 | ## Thermospheric options (relevant if tracer=T) : |
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138 | ##~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
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139 | # call thermosphere ? |
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140 | callthermos = .true. |
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141 | callthermos = .false. |
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142 | # WATER: included without cycle (only if water=.false.) |
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143 | thermoswater = .false. |
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144 | # call thermal conduction ? (only if callthermos=.true.) |
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145 | callconduct = .true. |
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146 | callconduct = .false. |
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147 | # call molecular viscosity ? (only if callthermos=.true.) |
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148 | callmolvis = .true. |
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149 | callmolvis = .false. |
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150 | # call molecular diffusion ? (only if callthermos=.true.) |
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151 | callmoldiff = .true. |
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152 | callmoldiff = .false. |
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153 | # call thermospheric photochemistry ? (only if callthermos=.true.) |
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154 | thermochem = .true. |
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155 | thermochem = .false. |
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156 | # call EUV heating ? (only if callthermos=.true.) |
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157 | calleuv=.true. |
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158 | calleuv=.false. |
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159 | #Method to include solar variability? |
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160 | #0-> Fixed EUV input 1-> Variability with E10.7 as observed |
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161 | solvarmod=1 |
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162 | # fixed E10.7 value (for solvarmod=0) |
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163 | # (min=80 , ave=140, max=320) |
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164 | fixed_euv_value=140 |
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165 | #Solar variability as observed for MY? (must be between MY23 and MY32) |
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166 | # (only matters if solvarmod=1) |
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167 | solvaryear=34 |
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168 | # value for the UV heating efficiency |
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169 | ##(experimental values between 0.19 and 0.23, lower values may |
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170 | ## be used to compensate for low 15 um cooling) |
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171 | euveff = 0.21 |
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172 | |
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173 | |
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174 | |
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