1 | MODULE trcbio_medusa |
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2 | !!====================================================================== |
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3 | !! *** MODULE trcbio *** |
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4 | !! TOP : MEDUSA |
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5 | !!====================================================================== |
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6 | !! History : |
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7 | !! - ! 1999-07 (M. Levy) original code |
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8 | !! - ! 2000-12 (E. Kestenare) assign parameters to name individual tracers |
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9 | !! - ! 2001-03 (M. Levy) LNO3 + dia2d |
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10 | !! 2.0 ! 2007-12 (C. Deltel, G. Madec) F90 |
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11 | !! - ! 2008-08 (K. Popova) adaptation for MEDUSA |
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12 | !! - ! 2008-11 (A. Yool) continuing adaptation for MEDUSA |
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13 | !! - ! 2010-03 (A. Yool) updated for branch inclusion |
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14 | !! - ! 2011-08 (A. Yool) updated for ROAM (see below) |
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15 | !! - ! 2013-03 (A. Yool) updated for iMARNET |
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16 | !! - ! 2013-05 (A. Yool) updated for v3.5 |
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17 | !! - ! 2014-08 (A. Yool, J. Palm) Add DMS module for UKESM1 model |
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18 | !!---------------------------------------------------------------------- |
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19 | !! |
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20 | #if defined key_roam |
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21 | !!---------------------------------------------------------------------- |
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22 | !! Updates for the ROAM project include: |
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23 | !! - addition of DIC, alkalinity, detrital carbon and oxygen tracers |
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24 | !! - addition of air-sea fluxes of CO2 and oxygen |
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25 | !! - periodic (monthly) calculation of full 3D carbonate chemistry |
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26 | !! - detrital C:N ratio now free to evolve dynamically |
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27 | !! - benthic storage pools |
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28 | !! |
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29 | !! Opportunity also taken to add functionality: |
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30 | !! - switch for Liebig Law (= most-limiting) nutrient uptake |
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31 | !! - switch for accelerated seafloor detritus remineralisation |
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32 | !! - switch for fast -> slow detritus transfer at seafloor |
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33 | !! - switch for ballast vs. Martin vs. Henson fast detritus remin. |
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34 | !! - per GMD referee remarks, xfdfrac3 introduced for grazed PDS |
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35 | !!---------------------------------------------------------------------- |
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36 | #endif |
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37 | !! |
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38 | #if defined key_medusa |
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39 | !!---------------------------------------------------------------------- |
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40 | !! MEDUSA bio-model |
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41 | !!---------------------------------------------------------------------- |
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42 | !! trc_bio_medusa : |
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43 | !!---------------------------------------------------------------------- |
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44 | USE oce_trc |
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45 | USE trc |
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46 | USE sms_medusa |
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47 | USE lbclnk |
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48 | USE prtctl_trc ! Print control for debugging |
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49 | USE trcsed_medusa |
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50 | USE sbc_oce ! surface forcing |
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51 | USE sbcrnf ! surface boundary condition: runoff variables |
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52 | USE in_out_manager ! I/O manager |
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53 | # if defined key_iomput |
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54 | USE iom |
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55 | # endif |
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56 | # if defined key_roam |
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57 | USE trcco2_medusa |
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58 | USE trcoxy_medusa |
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59 | !! Jpalm (08/08/2014) |
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60 | USE trcdms_medusa |
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61 | # endif |
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62 | !! AXY (18/01/12): brought in for benthic timestepping |
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63 | USE trcnam_trp ! AXY (24/05/2013) |
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64 | USE trdmxl_trc |
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65 | USE trdtrc_oce ! AXY (24/05/2013) |
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66 | |
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67 | !! AXY (30/01/14): necessary to find NaNs on HECTOR |
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68 | USE, INTRINSIC :: ieee_arithmetic |
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69 | |
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70 | IMPLICIT NONE |
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71 | PRIVATE |
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72 | |
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73 | PUBLIC trc_bio_medusa ! called in ??? |
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74 | |
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75 | !!* Substitution |
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76 | # include "domzgr_substitute.h90" |
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77 | !!---------------------------------------------------------------------- |
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78 | !! NEMO/TOP 2.0 , LOCEAN-IPSL (2007) |
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79 | !! $Id: trcbio.F90 1146 2008-06-25 11:42:56Z rblod $ |
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80 | !! Software governed by the CeCILL licence (modipsl/doc/NEMO_CeCILL.txt) |
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81 | !!---------------------------------------------------------------------- |
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82 | |
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83 | CONTAINS |
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84 | |
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85 | SUBROUTINE trc_bio_medusa( kt ) |
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86 | !!--------------------------------------------------------------------- |
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87 | !! *** ROUTINE trc_bio *** |
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88 | !! |
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89 | !! ** Purpose : compute the now trend due to biogeochemical processes |
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90 | !! and add it to the general trend of passive tracers equations |
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91 | !! |
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92 | !! ** Method : each now biological flux is calculated in function of now |
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93 | !! concentrations of tracers. |
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94 | !! depending on the tracer, these fluxes are sources or sinks. |
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95 | !! the total of the sources and sinks for each tracer |
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96 | !! is added to the general trend. |
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97 | !! |
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98 | !! tra = tra + zf...tra - zftra... |
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99 | !! | | |
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100 | !! | | |
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101 | !! source sink |
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102 | !! |
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103 | !! IF 'key_trc_diabio' defined , the biogeochemical trends |
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104 | !! for passive tracers are saved for futher diagnostics. |
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105 | !!--------------------------------------------------------------------- |
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106 | !! |
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107 | !! |
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108 | !!---------------------------------------------------------------------- |
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109 | !! Variable conventions |
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110 | !!---------------------------------------------------------------------- |
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111 | !! |
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112 | !! names: z*** - state variable |
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113 | !! f*** - function (or temporary variable used in part of a function) |
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114 | !! x*** - parameter |
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115 | !! b*** - right-hand part (sources and sinks) |
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116 | !! i*** - integer variable (usually used in yes/no flags) |
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117 | !! |
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118 | !! time (integer timestep) |
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119 | INTEGER, INTENT( in ) :: kt |
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120 | !! |
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121 | !! spatial array indices |
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122 | INTEGER :: ji,jj,jk,jn |
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123 | !! |
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124 | !! AXY (27/07/10): add in indices for depth horizons (for sinking flux |
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125 | !! and seafloor iron inputs) |
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126 | !! INTEGER :: i0100, i0200, i0500, i1000, i1100 |
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127 | !! |
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128 | !! model state variables |
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129 | REAL(wp) :: zchn,zchd,zphn,zphd,zpds,zzmi |
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130 | REAL(wp) :: zzme,zdet,zdtc,zdin,zsil,zfer |
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131 | REAL(wp) :: zage |
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132 | # if defined key_roam |
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133 | REAL(wp) :: zdic, zalk, zoxy |
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134 | REAL(wp) :: ztmp, zsal |
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135 | # endif |
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136 | !! |
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137 | !! integrated source and sink terms |
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138 | REAL(wp) :: b0 |
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139 | !! AXY (23/08/13): changed from individual variables for each flux to |
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140 | !! an array that holds all fluxes |
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141 | REAL(wp), DIMENSION(jp_medusa) :: btra |
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142 | !! |
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143 | !! primary production and chl related quantities |
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144 | REAL(wp) :: fthetan,faln,fchn1,fchn,fjln,fprn,frn |
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145 | REAL(wp) :: fthetad,fald,fchd1,fchd,fjld,fprd,frd |
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146 | !! AXY (03/02/11): add in Liebig terms |
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147 | REAL(wp) :: fpnlim, fpdlim |
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148 | !! AXY (16/07/09): add in Eppley curve functionality |
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149 | REAL(wp) :: loc_T,fun_T,xvpnT,xvpdT |
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150 | INTEGER :: ieppley |
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151 | !! AXY (01/03/10): add in mixed layer PP diagnostics |
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152 | REAL(wp) :: fprn_ml,fprd_ml |
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153 | !! |
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154 | !! nutrient limiting factors |
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155 | REAL(wp) :: fnln,ffln !! N and Fe |
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156 | REAL(wp) :: fnld,ffld,fsld,fsld2 !! N, Fe and Si |
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157 | !! |
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158 | !! silicon cycle |
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159 | REAL(wp) :: fsin,fnsi,fsin1,fnsi1,fnsi2,fprds,fsdiss |
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160 | !! |
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161 | !! iron cycle; includes parameters for Parekh et al. (2005) iron scheme |
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162 | REAL(wp) :: ffetop,ffebot,ffescav |
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163 | REAL(wp) :: xLgF, xFeT, xFeF, xFeL, xFree !! state variables for iron-ligand system |
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164 | REAL(wp) :: xb_coef_tmp, xb2M4ac !! iron-ligand parameters |
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165 | REAL(wp) :: xmaxFeF,fdeltaFe !! max Fe' parameters |
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166 | !! |
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167 | !! local parameters for Moore et al. (2004) alternative scavenging scheme |
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168 | REAL(wp) :: fbase_scav,fscal_sink,fscal_part,fscal_scav |
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169 | !! |
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170 | !! local parameters for Moore et al. (2008) alternative scavenging scheme |
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171 | REAL(wp) :: fscal_csink,fscal_sisink,fscal_casink |
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172 | !! |
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173 | !! local parameters for Galbraith et al. (2010) alternative scavenging scheme |
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174 | REAL(wp) :: xCscav1, xCscav2, xk_org, xORGscav !! organic portion of scavenging |
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175 | REAL(wp) :: xk_inorg, xINORGscav !! inorganic portion of scavenging |
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176 | !! |
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177 | !! microzooplankton grazing |
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178 | REAL(wp) :: fmi1,fmi,fgmipn,fgmid,fgmidc |
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179 | REAL(wp) :: finmi,ficmi,fstarmi,fmith,fmigrow,fmiexcr,fmiresp |
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180 | !! |
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181 | !! mesozooplankton grazing |
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182 | REAL(wp) :: fme1,fme,fgmepn,fgmepd,fgmepds,fgmezmi,fgmed,fgmedc |
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183 | REAL(wp) :: finme,ficme,fstarme,fmeth,fmegrow,fmeexcr,fmeresp |
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184 | !! |
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185 | !! mortality/Remineralisation (defunct parameter "fz" removed) |
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186 | REAL(wp) :: fdpn,fdpd,fdpds,fdzmi,fdzme,fdd |
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187 | # if defined key_roam |
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188 | REAL(wp) :: fddc |
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189 | # endif |
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190 | REAL(wp) :: fdpn2,fdpd2,fdpds2,fdzmi2,fdzme2 |
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191 | REAL(wp) :: fslown, fslownflux |
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192 | REAL(wp) :: fslowc, fslowcflux |
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193 | REAL(wp) :: fregen,fregensi |
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194 | REAL(wp), DIMENSION(jpi,jpj) :: fregenfast,fregenfastsi |
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195 | # if defined key_roam |
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196 | REAL(wp) :: fregenc |
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197 | REAL(wp), DIMENSION(jpi,jpj) :: fregenfastc |
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198 | # endif |
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199 | !! |
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200 | !! particle flux |
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201 | REAL(WP) :: fthk,fdep,fdep1,fdep2,flat,fcaco3 |
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202 | REAL(WP) :: ftempn,ftempsi,ftempfe,ftempc,ftempca |
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203 | REAL(wp) :: freminn,freminsi,freminfe,freminc,freminca |
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204 | REAL(wp), DIMENSION(jpi,jpj) :: ffastn,ffastsi,ffastfe,ffastc,ffastca |
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205 | REAL(wp) :: fleftn,fleftsi,fleftfe,fleftc,fleftca |
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206 | REAL(wp) :: fheren,fheresi,fherefe,fherec,fhereca |
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207 | REAL(wp) :: fprotf |
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208 | REAL(wp) :: fsedn,fsedsi,fsedfe,fsedc,fsedca |
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209 | REAL(wp), DIMENSION(jpi,jpj) :: fccd |
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210 | REAL(wp) :: fccd_dep |
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211 | !! |
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212 | !! AXY (06/07/11): alternative fast detritus schemes |
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213 | REAL(wp) :: fb_val, fl_sst |
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214 | !! |
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215 | !! AXY (08/07/11): fate of fast detritus reaching the seafloor |
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216 | REAL(wp) :: ffast2slown,ffast2slowfe,ffast2slowc |
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217 | !! |
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218 | !! conservation law |
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219 | REAL(wp) :: fnit0,fsil0,ffer0 |
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220 | # if defined key_roam |
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221 | REAL(wp) :: fcar0,falk0,foxy0 |
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222 | # endif |
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223 | !! |
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224 | !! temporary variables |
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225 | REAL(wp) :: fq0,fq1,fq2,fq3,fq4,fq5,fq6,fq7,fq8,fq9 |
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226 | !! |
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227 | !! water column nutrient and flux integrals |
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228 | REAL(wp) :: ftot_n,ftot_si,ftot_fe |
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229 | REAL(wp), DIMENSION(jpi,jpj) :: fflx_n,fflx_si,fflx_fe |
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230 | REAL(wp), DIMENSION(jpi,jpj) :: fifd_n,fifd_si,fifd_fe |
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231 | REAL(wp), DIMENSION(jpi,jpj) :: fofd_n,fofd_si,fofd_fe |
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232 | # if defined key_roam |
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233 | REAL(wp) :: ftot_c,ftot_a,ftot_o2 |
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234 | REAL(wp), DIMENSION(jpi,jpj) :: fflx_c,fflx_a,fflx_o2 |
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235 | REAL(wp), DIMENSION(jpi,jpj) :: fifd_c,fifd_a,fifd_o2 |
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236 | REAL(wp), DIMENSION(jpi,jpj) :: fofd_c,fofd_a,fofd_o2 |
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237 | # endif |
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238 | !! |
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239 | !! zooplankton grazing integrals |
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240 | REAL(wp), DIMENSION(jpi,jpj) :: fzmi_i,fzmi_o,fzme_i,fzme_o |
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241 | !! |
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242 | !! limitation term temporary variables |
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243 | REAL(wp), DIMENSION(jpi,jpj) :: ftot_pn,ftot_pd |
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244 | REAL(wp), DIMENSION(jpi,jpj) :: ftot_zmi,ftot_zme,ftot_det,ftot_dtc |
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245 | !! use ballast scheme (1) or simple exponential scheme (0; a conservation test) |
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246 | INTEGER :: iball |
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247 | !! use biological fluxes (1) or not (0) |
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248 | INTEGER :: ibio_switch |
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249 | !! |
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250 | !! diagnose fluxes (should only be used in 1D runs) |
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251 | INTEGER :: idf, idfval |
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252 | !! |
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253 | !! nitrogen and silicon production and consumption |
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254 | REAL(wp) :: fn_prod, fn_cons, fs_prod, fs_cons |
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255 | REAL(wp), DIMENSION(jpi,jpj) :: fnit_prod, fnit_cons, fsil_prod, fsil_cons |
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256 | # if defined key_roam |
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257 | !! |
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258 | !! flags to help with calculating the position of the CCD |
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259 | INTEGER, DIMENSION(jpi,jpj) :: i2_omcal,i2_omarg |
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260 | !! |
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261 | !! ROAM air-sea flux and diagnostic parameters |
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262 | REAL(wp) :: f_wind, f_pco2a |
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263 | REAL(wp) :: f_ph, f_pco2w, f_h2co3, f_hco3, f_co3, f_co2flux |
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264 | REAL(wp) :: f_TDIC, f_TALK, f_dcf, f_henry |
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265 | REAL(wp) :: f_uwind, f_vwind, f_pp0 |
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266 | REAL(wp) :: f_kw660, f_o2flux, f_o2sat |
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267 | REAL(wp), DIMENSION(jpi,jpj) :: f_omcal, f_omarg |
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268 | INTEGER :: iters |
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269 | REAL(wp) :: f_year |
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270 | INTEGER :: i_year |
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271 | INTEGER :: iyr1, iyr2 |
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272 | !! |
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273 | !! carbon, alkalinity production and consumption |
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274 | REAL(wp) :: fc_prod, fc_cons, fa_prod, fa_cons |
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275 | REAL(wp) :: fcomm_resp |
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276 | REAL(wp), DIMENSION(jpi,jpj) :: fcar_prod, fcar_cons |
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277 | !! |
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278 | !! oxygen production and consumption (and non-consumption) |
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279 | REAL(wp) :: fo2_prod, fo2_cons, fo2_ncons, fo2_ccons |
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280 | REAL(wp), DIMENSION(jpi,jpj) :: foxy_prod, foxy_cons, foxy_anox |
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281 | !! Jpalm (11-08-2014) |
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282 | !! add DMS in MEDUSA for UKESM1 model |
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283 | REAL(wp) :: dms_surf |
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284 | !! AXY (13/03/15): add in other DMS calculations |
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285 | REAL(wp) :: dms_andr, dms_simo, dms_aran, dms_hall |
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286 | # endif |
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287 | !! |
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288 | !! benthic fluxes |
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289 | INTEGER :: ibenthic |
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290 | REAL(wp), DIMENSION(jpi,jpj) :: f_sbenin_n, f_sbenin_fe, f_sbenin_c |
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291 | REAL(wp), DIMENSION(jpi,jpj) :: f_fbenin_n, f_fbenin_fe, f_fbenin_si, f_fbenin_c, f_fbenin_ca |
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292 | REAL(wp), DIMENSION(jpi,jpj) :: f_benout_n, f_benout_fe, f_benout_si, f_benout_c, f_benout_ca |
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293 | REAL(wp) :: zfact |
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294 | !! |
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295 | !! benthic fluxes of CaCO3 that shouldn't happen because of lysocline |
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296 | REAL(wp), DIMENSION(jpi,jpj) :: f_benout_lyso_ca |
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297 | !! |
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298 | !! riverine fluxes |
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299 | REAL(wp), DIMENSION(jpi,jpj) :: f_runoff, f_riv_n, f_riv_si, f_riv_c, f_riv_alk |
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300 | !! AXY (19/07/12): variables for local riverine fluxes to handle inputs below surface |
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301 | REAL(wp) :: f_riv_loc_n, f_riv_loc_si, f_riv_loc_c, f_riv_loc_alk |
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302 | !! |
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303 | !! horizontal grid location |
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304 | REAL(wp) :: flatx, flonx |
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305 | |
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306 | !!--------------------------------------------------------------------- |
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307 | |
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308 | !! AXY (20/11/14): alter this to report on first MEDUSA call |
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309 | !! IF( kt == nit000 ) THEN |
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310 | IF( kt == nittrc000 ) THEN |
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311 | IF(lwp) WRITE(numout,*) |
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312 | IF(lwp) WRITE(numout,*) ' trc_bio: MEDUSA bio-model' |
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313 | IF(lwp) WRITE(numout,*) ' ~~~~~~~' |
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314 | IF(lwp) WRITE(numout,*) ' kt =',kt |
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315 | ENDIF |
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316 | |
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317 | !! AXY (13/01/12): is benthic model properly interactive? 0 = no, 1 = yes |
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318 | ibenthic = 1 |
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319 | |
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320 | !! not sure what this is for; it's not used anywhere; commenting out |
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321 | !! fbodn(:,:) = 0.e0 |
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322 | |
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323 | !! |
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324 | IF( ln_diatrc ) THEN |
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325 | !! blank 2D diagnostic array |
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326 | trc2d(:,:,:) = 0.e0 |
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327 | !! |
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328 | !! blank 3D diagnostic array |
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329 | trc3d(:,:,:,:) = 0.e0 |
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330 | ENDIF |
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331 | |
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332 | !!---------------------------------------------------------------------- |
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333 | !! b0 is present for debugging purposes; using b0 = 0 sets the tendency |
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334 | !! terms of all biological equations to 0. |
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335 | !!---------------------------------------------------------------------- |
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336 | !! |
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337 | !! AXY (03/09/14): probably not the smartest move ever, but it'll fit |
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338 | !! the bill for now; another item on the things-to-sort- |
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339 | !! out-in-the-future list ... |
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340 | # if defined key_kill_medusa |
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341 | b0 = 0. |
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342 | # else |
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343 | b0 = 1. |
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344 | # endif |
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345 | !!---------------------------------------------------------------------- |
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346 | !! fast detritus ballast scheme (0 = no; 1 = yes) |
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347 | !! alternative to ballast scheme is same scheme but with no ballast |
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348 | !! protection (not dissimilar to Martin et al., 1987) |
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349 | !!---------------------------------------------------------------------- |
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350 | !! |
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351 | iball = 1 |
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352 | |
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353 | !!---------------------------------------------------------------------- |
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354 | !! full flux diagnostics (0 = no; 1 = yes); appear in ocean.output |
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355 | !! these should *only* be used in 1D since they give comprehensive |
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356 | !! output for ecological functions in the model; primarily used in |
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357 | !! debugging |
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358 | !!---------------------------------------------------------------------- |
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359 | !! |
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360 | idf = 0 |
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361 | !! |
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362 | !! timer mechanism |
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363 | if (kt/120*120.eq.kt) then |
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364 | idfval = 1 |
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365 | else |
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366 | idfval = 0 |
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367 | endif |
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368 | |
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369 | !!---------------------------------------------------------------------- |
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370 | !! blank fast-sinking detritus 2D fields |
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371 | !!---------------------------------------------------------------------- |
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372 | !! |
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373 | ffastn(:,:) = 0.0 !! organic nitrogen |
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374 | ffastsi(:,:) = 0.0 !! biogenic silicon |
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375 | ffastfe(:,:) = 0.0 !! organic iron |
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376 | ffastc(:,:) = 0.0 !! organic carbon |
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377 | ffastca(:,:) = 0.0 !! biogenic calcium carbonate |
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378 | !! |
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379 | fregenfast(:,:) = 0.0 !! integrated N regeneration (fast detritus) |
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380 | fregenfastsi(:,:) = 0.0 !! integrated Si regeneration (fast detritus) |
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381 | # if defined key_roam |
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382 | fregenfastc(:,:) = 0.0 !! integrated C regeneration (fast detritus) |
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383 | # endif |
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384 | !! |
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385 | fccd(:,:) = 0.0 !! last depth level before CCD |
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386 | |
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387 | !!---------------------------------------------------------------------- |
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388 | !! blank nutrient/flux inventories |
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389 | !!---------------------------------------------------------------------- |
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390 | !! |
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391 | fflx_n(:,:) = 0.0 !! nitrogen flux total |
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392 | fflx_si(:,:) = 0.0 !! silicon flux total |
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393 | fflx_fe(:,:) = 0.0 !! iron flux total |
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394 | fifd_n(:,:) = 0.0 !! nitrogen fast detritus production |
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395 | fifd_si(:,:) = 0.0 !! silicon fast detritus production |
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396 | fifd_fe(:,:) = 0.0 !! iron fast detritus production |
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397 | fofd_n(:,:) = 0.0 !! nitrogen fast detritus remineralisation |
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398 | fofd_si(:,:) = 0.0 !! silicon fast detritus remineralisation |
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399 | fofd_fe(:,:) = 0.0 !! iron fast detritus remineralisation |
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400 | # if defined key_roam |
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401 | fflx_c(:,:) = 0.0 !! carbon flux total |
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402 | fflx_a(:,:) = 0.0 !! alkalinity flux total |
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403 | fflx_o2(:,:) = 0.0 !! oxygen flux total |
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404 | fifd_c(:,:) = 0.0 !! carbon fast detritus production |
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405 | fifd_a(:,:) = 0.0 !! alkalinity fast detritus production |
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406 | fifd_o2(:,:) = 0.0 !! oxygen fast detritus production |
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407 | fofd_c(:,:) = 0.0 !! carbon fast detritus remineralisation |
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408 | fofd_a(:,:) = 0.0 !! alkalinity fast detritus remineralisation |
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409 | fofd_o2(:,:) = 0.0 !! oxygen fast detritus remineralisation |
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410 | !! |
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411 | fnit_prod(:,:) = 0.0 !! (organic) nitrogen production |
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412 | fnit_cons(:,:) = 0.0 !! (organic) nitrogen consumption |
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413 | fsil_prod(:,:) = 0.0 !! (inorganic) silicon production |
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414 | fsil_cons(:,:) = 0.0 !! (inorganic) silicon consumption |
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415 | fcar_prod(:,:) = 0.0 !! (organic) carbon production |
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416 | fcar_cons(:,:) = 0.0 !! (organic) carbon consumption |
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417 | !! |
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418 | foxy_prod(:,:) = 0.0 !! oxygen production |
---|
419 | foxy_cons(:,:) = 0.0 !! oxygen consumption |
---|
420 | foxy_anox(:,:) = 0.0 !! unrealised oxygen consumption |
---|
421 | # endif |
---|
422 | ftot_pn(:,:) = 0.0 !! integrated non-diatom phytoplankton |
---|
423 | ftot_pd(:,:) = 0.0 !! integrated diatom phytoplankton |
---|
424 | ftot_zmi(:,:) = 0.0 !! integrated microzooplankton |
---|
425 | ftot_zme(:,:) = 0.0 !! integrated mesozooplankton |
---|
426 | ftot_det(:,:) = 0.0 !! integrated slow detritus, nitrogen |
---|
427 | ftot_dtc(:,:) = 0.0 !! integrated slow detritus, carbon |
---|
428 | !! |
---|
429 | fzmi_i(:,:) = 0.0 !! material grazed by microzooplankton |
---|
430 | fzmi_o(:,:) = 0.0 !! ... sum of fate of this material |
---|
431 | fzme_i(:,:) = 0.0 !! material grazed by mesozooplankton |
---|
432 | fzme_o(:,:) = 0.0 !! ... sum of fate of this material |
---|
433 | !! |
---|
434 | f_sbenin_n(:,:) = 0.0 !! slow detritus N -> benthic pool |
---|
435 | f_sbenin_fe(:,:) = 0.0 !! slow detritus Fe -> benthic pool |
---|
436 | f_sbenin_c(:,:) = 0.0 !! slow detritus C -> benthic pool |
---|
437 | f_fbenin_n(:,:) = 0.0 !! fast detritus N -> benthic pool |
---|
438 | f_fbenin_fe(:,:) = 0.0 !! fast detritus Fe -> benthic pool |
---|
439 | f_fbenin_si(:,:) = 0.0 !! fast detritus Si -> benthic pool |
---|
440 | f_fbenin_c(:,:) = 0.0 !! fast detritus C -> benthic pool |
---|
441 | f_fbenin_ca(:,:) = 0.0 !! fast detritus Ca -> benthic pool |
---|
442 | !! |
---|
443 | f_benout_n(:,:) = 0.0 !! benthic N pool -> dissolved |
---|
444 | f_benout_fe(:,:) = 0.0 !! benthic Fe pool -> dissolved |
---|
445 | f_benout_si(:,:) = 0.0 !! benthic Si pool -> dissolved |
---|
446 | f_benout_c(:,:) = 0.0 !! benthic C pool -> dissolved |
---|
447 | f_benout_ca(:,:) = 0.0 !! benthic Ca pool -> dissolved |
---|
448 | !! |
---|
449 | f_benout_lyso_ca(:,:) = 0.0 !! benthic Ca pool -> dissolved (when it shouldn't!) |
---|
450 | !! |
---|
451 | f_runoff(:,:) = 0.0 !! riverine runoff |
---|
452 | f_riv_n(:,:) = 0.0 !! riverine N input |
---|
453 | f_riv_si(:,:) = 0.0 !! riverine Si input |
---|
454 | f_riv_c(:,:) = 0.0 !! riverine C input |
---|
455 | f_riv_alk(:,:) = 0.0 !! riverine alk input |
---|
456 | |
---|
457 | # if defined key_axy_nancheck |
---|
458 | DO jn = 1,jptra |
---|
459 | !! fq0 = MINVAL(trn(:,:,:,jn)) |
---|
460 | !! fq1 = MAXVAL(trn(:,:,:,jn)) |
---|
461 | fq2 = SUM(trn(:,:,:,jn)) |
---|
462 | !! if (lwp) write (numout,'(a,2i6,3(1x,1pe15.5))') 'NAN-CHECK', & |
---|
463 | !! & kt, jn, fq0, fq1, fq2 |
---|
464 | !! AXY (30/01/14): much to our surprise, the next line doesn't work on HECTOR |
---|
465 | !! and has been replaced here with a specialist routine |
---|
466 | !! if (fq2 /= fq2 ) then |
---|
467 | if ( ieee_is_nan( fq2 ) ) then |
---|
468 | !! there's a NaN here |
---|
469 | if (lwp) write(numout,*) 'NAN detected in field', jn, 'at time', kt, 'at position:' |
---|
470 | DO jk = 1,jpk |
---|
471 | DO jj = 1,jpj |
---|
472 | DO ji = 1,jpi |
---|
473 | !! AXY (30/01/14): "isnan" problem on HECTOR |
---|
474 | !! if (trn(ji,jj,jk,jn) /= trn(ji,jj,jk,jn)) then |
---|
475 | if ( ieee_is_nan( trn(ji,jj,jk,jn) ) ) then |
---|
476 | if (lwp) write (numout,'(a,1pe12.2,4i6)') 'NAN-CHECK', & |
---|
477 | & tmask(ji,jj,jk), ji, jj, jk, jn |
---|
478 | endif |
---|
479 | enddo |
---|
480 | enddo |
---|
481 | enddo |
---|
482 | CALL ctl_stop( 'trcbio_medusa, NAN in incoming tracer field' ) |
---|
483 | endif |
---|
484 | ENDDO |
---|
485 | CALL flush(numout) |
---|
486 | # endif |
---|
487 | |
---|
488 | # if defined key_roam |
---|
489 | !!---------------------------------------------------------------------- |
---|
490 | !! calculate atmospheric pCO2 |
---|
491 | !!---------------------------------------------------------------------- |
---|
492 | !! |
---|
493 | !! what's atmospheric pCO2 doing? (data start in 1859) |
---|
494 | iyr1 = nyear - 1859 + 1 |
---|
495 | iyr2 = iyr1 + 1 |
---|
496 | if (iyr1 .le. 1) then |
---|
497 | !! before 1860 |
---|
498 | f_pco2a = hist_pco2(1) |
---|
499 | elseif (iyr2 .ge. 242) then |
---|
500 | !! after 2099 |
---|
501 | f_pco2a = hist_pco2(242) |
---|
502 | else |
---|
503 | !! just right |
---|
504 | fq0 = hist_pco2(iyr1) |
---|
505 | fq1 = hist_pco2(iyr2) |
---|
506 | fq2 = real(nsec_day) / (60.0 * 60.0 * 24.0) |
---|
507 | !! AXY (14/06/12): tweaked to make more sense (and be correct) |
---|
508 | # if defined key_bs_axy_yrlen |
---|
509 | fq3 = (real(nday_year) - 1.0 + fq2) / 360.0 !! bugfix: for 360d year with HadGEM2-ES forcing |
---|
510 | # else |
---|
511 | fq3 = (real(nday_year) - 1.0 + fq2) / 365.0 !! original use of 365 days (not accounting for leap year or 360d year) |
---|
512 | # endif |
---|
513 | fq4 = (fq0 * (1.0 - fq3)) + (fq1 * fq3) |
---|
514 | f_pco2a = fq4 |
---|
515 | endif |
---|
516 | # if defined key_axy_pi_co2 |
---|
517 | f_pco2a = hist_pco2(1) |
---|
518 | IF(lwp) WRITE(numout,*) ' MEDUSA atm pCO2 = FIXED' |
---|
519 | # endif |
---|
520 | !! IF(lwp) WRITE(numout,*) ' MEDUSA nyear =', nyear |
---|
521 | !! IF(lwp) WRITE(numout,*) ' MEDUSA nsec_day =', real(nsec_day) |
---|
522 | !! IF(lwp) WRITE(numout,*) ' MEDUSA nday_year =', real(nday_year) |
---|
523 | !! AXY (29/01/14): remove surplus diagnostics |
---|
524 | !! IF(lwp) WRITE(numout,*) ' MEDUSA fq0 =', fq0 |
---|
525 | !! IF(lwp) WRITE(numout,*) ' MEDUSA fq1 =', fq1 |
---|
526 | !! IF(lwp) WRITE(numout,*) ' MEDUSA fq2 =', fq2 |
---|
527 | !! IF(lwp) WRITE(numout,*) ' MEDUSA fq3 =', fq3 |
---|
528 | IF(lwp) WRITE(numout,*) ' MEDUSA atm pCO2 =', f_pco2a |
---|
529 | # endif |
---|
530 | |
---|
531 | # if defined key_roam |
---|
532 | !! AXY (20/11/14): alter to call on first MEDUSA timestep |
---|
533 | !! IF( kt == nit000 .or. mod(kt,1920) == 0 ) THEN |
---|
534 | IF( kt == nittrc000 .or. mod(kt,1920) == 0 ) THEN |
---|
535 | !!---------------------------------------------------------------------- |
---|
536 | !! Calculate the carbonate chemistry for the whole ocean on the first |
---|
537 | !! simulation timestep and every month subsequently; the resulting 3D |
---|
538 | !! field of omega calcite is used to determine the depth of the CCD |
---|
539 | !!---------------------------------------------------------------------- |
---|
540 | !! |
---|
541 | IF(lwp) WRITE(numout,*) ' MEDUSA calculating all carbonate chemistry at kt =', kt |
---|
542 | !! blank flags |
---|
543 | i2_omcal(:,:) = 0 |
---|
544 | i2_omarg(:,:) = 0 |
---|
545 | !! loop over 3D space |
---|
546 | DO jk = 1,jpk |
---|
547 | DO jj = 2,jpjm1 |
---|
548 | DO ji = 2,jpim1 |
---|
549 | !! OPEN wet point IF..THEN loop |
---|
550 | if (tmask(ji,jj,jk).eq.1) then |
---|
551 | !! carbonate chemistry |
---|
552 | fdep2 = fsdept(ji,jj,jk) !! set up level midpoint |
---|
553 | !! set up required state variables |
---|
554 | zdic = max(0.,trn(ji,jj,jk,jpdic)) !! dissolved inorganic carbon |
---|
555 | zalk = max(0.,trn(ji,jj,jk,jpalk)) !! alkalinity |
---|
556 | ztmp = tsn(ji,jj,jk,jp_tem) !! temperature |
---|
557 | zsal = tsn(ji,jj,jk,jp_sal) !! salinity |
---|
558 | !! |
---|
559 | !! AXY (28/02/14): check input fields |
---|
560 | if (ztmp .lt. -3.0 .or. ztmp .gt. 40.0 ) then |
---|
561 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: T WARNING 3D, ', & |
---|
562 | tsb(ji,jj,jk,jp_tem), tsn(ji,jj,jk,jp_tem), ' at (', & |
---|
563 | ji, ',', jj, ',', jk, ') at time', kt |
---|
564 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: T SWITCHING 3D, ', & |
---|
565 | tsn(ji,jj,jk,jp_tem), ' -> ', tsb(ji,jj,jk,jp_tem) |
---|
566 | ztmp = tsb(ji,jj,jk,jp_tem) !! temperature |
---|
567 | endif |
---|
568 | if (zsal .lt. 0.0 .or. zsal .gt. 45.0 ) then |
---|
569 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: S WARNING 3D, ', & |
---|
570 | tsb(ji,jj,jk,jp_sal), tsn(ji,jj,jk,jp_sal), ' at (', & |
---|
571 | ji, ',', jj, ',', jk, ') at time', kt |
---|
572 | endif |
---|
573 | !! calculate carbonate chemistry at grid cell midpoint |
---|
574 | CALL trc_co2_medusa( ztmp, zsal, zdic, zalk, fdep2, 5.0, f_pco2a, & ! inputs |
---|
575 | f_ph, f_pco2w, f_h2co3, f_hco3, f_co3, f_omcal(ji,jj), & ! outputs |
---|
576 | f_omarg(ji,jj), f_co2flux, f_TDIC, f_TALK, f_dcf, f_henry, iters) ! outputs |
---|
577 | !! |
---|
578 | !! AXY (28/02/14): check output fields |
---|
579 | if (iters .eq. 25) then |
---|
580 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: 3D ITERS WARNING, ', & |
---|
581 | iters, ' AT (', ji, ', ', jj, ', ', jk, ') AT ', kt |
---|
582 | endif |
---|
583 | !! store 3D outputs |
---|
584 | f3_pH(ji,jj,jk) = f_ph |
---|
585 | f3_h2co3(ji,jj,jk) = f_h2co3 |
---|
586 | f3_hco3(ji,jj,jk) = f_hco3 |
---|
587 | f3_co3(ji,jj,jk) = f_co3 |
---|
588 | f3_omcal(ji,jj,jk) = f_omcal(ji,jj) |
---|
589 | f3_omarg(ji,jj,jk) = f_omarg(ji,jj) |
---|
590 | !! CCD calculation: calcite |
---|
591 | if (i2_omcal(ji,jj) .eq. 0 .and. f_omcal(ji,jj) .lt. 1.0) then |
---|
592 | if (jk .eq. 1) then |
---|
593 | f2_ccd_cal(ji,jj) = fdep2 |
---|
594 | else |
---|
595 | fq0 = f3_omcal(ji,jj,jk-1) - f_omcal(ji,jj) |
---|
596 | fq1 = f3_omcal(ji,jj,jk-1) - 1.0 |
---|
597 | fq2 = fq1 / (fq0 + tiny(fq0)) |
---|
598 | fq3 = fdep2 - fsdept(ji,jj,jk-1) |
---|
599 | fq4 = fq2 * fq3 |
---|
600 | f2_ccd_cal(ji,jj) = fsdept(ji,jj,jk-1) + fq4 |
---|
601 | endif |
---|
602 | i2_omcal(ji,jj) = 1 |
---|
603 | endif |
---|
604 | if ( i2_omcal(ji,jj) .eq. 0 .and. jk .eq. (mbathy(ji,jj)-1) ) then |
---|
605 | !! reached seafloor and still no dissolution; set to seafloor (W-point) |
---|
606 | f2_ccd_cal(ji,jj) = fsdepw(ji,jj,jk+1) |
---|
607 | i2_omcal(ji,jj) = 1 |
---|
608 | endif |
---|
609 | !! CCD calculation: aragonite |
---|
610 | if (i2_omarg(ji,jj) .eq. 0 .and. f_omarg(ji,jj) .lt. 1.0) then |
---|
611 | if (jk .eq. 1) then |
---|
612 | f2_ccd_arg(ji,jj) = fdep2 |
---|
613 | else |
---|
614 | fq0 = f3_omarg(ji,jj,jk-1) - f_omarg(ji,jj) |
---|
615 | fq1 = f3_omarg(ji,jj,jk-1) - 1.0 |
---|
616 | fq2 = fq1 / (fq0 + tiny(fq0)) |
---|
617 | fq3 = fdep2 - fsdept(ji,jj,jk-1) |
---|
618 | fq4 = fq2 * fq3 |
---|
619 | f2_ccd_arg(ji,jj) = fsdept(ji,jj,jk-1) + fq4 |
---|
620 | endif |
---|
621 | i2_omarg(ji,jj) = 1 |
---|
622 | endif |
---|
623 | if ( i2_omarg(ji,jj) .eq. 0 .and. jk .eq. (mbathy(ji,jj)-1) ) then |
---|
624 | !! reached seafloor and still no dissolution; set to seafloor (W-point) |
---|
625 | f2_ccd_arg(ji,jj) = fsdepw(ji,jj,jk+1) |
---|
626 | i2_omarg(ji,jj) = 1 |
---|
627 | endif |
---|
628 | endif |
---|
629 | ENDDO |
---|
630 | ENDDO |
---|
631 | ENDDO |
---|
632 | ENDIF |
---|
633 | # endif |
---|
634 | |
---|
635 | !!---------------------------------------------------------------------- |
---|
636 | !! MEDUSA has unified equation through the water column |
---|
637 | !! (Diff. from LOBSTER which has two sets: bio- and non-bio layers) |
---|
638 | !! Statement below in LOBSTER is different: DO jk = 1, jpkbm1 |
---|
639 | !!---------------------------------------------------------------------- |
---|
640 | !! |
---|
641 | !! NOTE: the ordering of the loops below differs from that of some other |
---|
642 | !! models; looping over the vertical dimension is the outermost loop and |
---|
643 | !! this complicates some calculations (e.g. storage of vertical fluxes |
---|
644 | !! that can otherwise be done via a singular variable require 2D fields |
---|
645 | !! here); however, these issues are relatively easily resolved, but the |
---|
646 | !! loops CANNOT be reordered without potentially causing code efficiency |
---|
647 | !! problems (e.g. array indexing means that reordering the loops would |
---|
648 | !! require skipping between widely-spaced memory location; potentially |
---|
649 | !! outside those immediately cached) |
---|
650 | !! |
---|
651 | !! OPEN vertical loop |
---|
652 | DO jk = 1,jpk |
---|
653 | !! OPEN horizontal loops |
---|
654 | DO jj = 2,jpjm1 |
---|
655 | DO ji = 2,jpim1 |
---|
656 | !! OPEN wet point IF..THEN loop |
---|
657 | if (tmask(ji,jj,jk).eq.1) then |
---|
658 | |
---|
659 | !!====================================================================== |
---|
660 | !! SETUP LOCAL GRID CELL |
---|
661 | !!====================================================================== |
---|
662 | !! |
---|
663 | !!--------------------------------------------------------------------- |
---|
664 | !! Some notes on grid vertical structure |
---|
665 | !! - fsdepw(ji,jj,jk) is the depth of the upper surface of level jk |
---|
666 | !! - fsde3w(ji,jj,jk) is *approximately* the midpoint of level jk |
---|
667 | !! - fse3t(ji,jj,jk) is the thickness of level jk |
---|
668 | !!--------------------------------------------------------------------- |
---|
669 | !! |
---|
670 | !! AXY (11/12/08): set up level thickness |
---|
671 | fthk = fse3t(ji,jj,jk) |
---|
672 | !! AXY (25/02/10): set up level depth (top of level) |
---|
673 | fdep = fsdepw(ji,jj,jk) |
---|
674 | !! AXY (01/03/10): set up level depth (bottom of level) |
---|
675 | fdep1 = fdep + fthk |
---|
676 | !! AXY (17/05/13): where am I? |
---|
677 | flatx = gphit(ji,jj) |
---|
678 | flonx = glamt(ji,jj) |
---|
679 | !! |
---|
680 | !! set up model tracers |
---|
681 | !! negative values of state variables are not allowed to |
---|
682 | !! contribute to the calculated fluxes |
---|
683 | zchn = max(0.,trn(ji,jj,jk,jpchn)) !! non-diatom chlorophyll |
---|
684 | zchd = max(0.,trn(ji,jj,jk,jpchd)) !! diatom chlorophyll |
---|
685 | zphn = max(0.,trn(ji,jj,jk,jpphn)) !! non-diatoms |
---|
686 | zphd = max(0.,trn(ji,jj,jk,jpphd)) !! diatoms |
---|
687 | zpds = max(0.,trn(ji,jj,jk,jppds)) !! diatom silicon |
---|
688 | !! AXY (28/01/10): probably need to take account of chl/biomass connection |
---|
689 | if (zchn.eq.0.) zphn = 0. |
---|
690 | if (zchd.eq.0.) zphd = 0. |
---|
691 | if (zphn.eq.0.) zchn = 0. |
---|
692 | if (zphd.eq.0.) zchd = 0. |
---|
693 | !! AXY (23/01/14): duh - why did I forget diatom silicon? |
---|
694 | if (zpds.eq.0.) zphd = 0. |
---|
695 | if (zphd.eq.0.) zpds = 0. |
---|
696 | zzmi = max(0.,trn(ji,jj,jk,jpzmi)) !! microzooplankton |
---|
697 | zzme = max(0.,trn(ji,jj,jk,jpzme)) !! mesozooplankton |
---|
698 | zdet = max(0.,trn(ji,jj,jk,jpdet)) !! detrital nitrogen |
---|
699 | zdin = max(0.,trn(ji,jj,jk,jpdin)) !! dissolved inorganic nitrogen |
---|
700 | zsil = max(0.,trn(ji,jj,jk,jpsil)) !! dissolved silicic acid |
---|
701 | zfer = max(0.,trn(ji,jj,jk,jpfer)) !! dissolved "iron" |
---|
702 | # if defined key_roam |
---|
703 | zdtc = max(0.,trn(ji,jj,jk,jpdtc)) !! detrital carbon |
---|
704 | zdic = max(0.,trn(ji,jj,jk,jpdic)) !! dissolved inorganic carbon |
---|
705 | zalk = max(0.,trn(ji,jj,jk,jpalk)) !! alkalinity |
---|
706 | zoxy = max(0.,trn(ji,jj,jk,jpoxy)) !! oxygen |
---|
707 | !! |
---|
708 | !! also need physical parameters for gas exchange calculations |
---|
709 | ztmp = tsn(ji,jj,jk,jp_tem) |
---|
710 | zsal = tsn(ji,jj,jk,jp_sal) |
---|
711 | !! |
---|
712 | !! AXY (28/02/14): check input fields |
---|
713 | if (ztmp .lt. -3.0 .or. ztmp .gt. 40.0 ) then |
---|
714 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: T WARNING 2D, ', & |
---|
715 | tsb(ji,jj,jk,jp_tem), tsn(ji,jj,jk,jp_tem), ' at (', & |
---|
716 | ji, ',', jj, ',', jk, ') at time', kt |
---|
717 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: T SWITCHING 2D, ', & |
---|
718 | tsn(ji,jj,jk,jp_tem), ' -> ', tsb(ji,jj,jk,jp_tem) |
---|
719 | ztmp = tsb(ji,jj,jk,jp_tem) !! temperature |
---|
720 | endif |
---|
721 | if (zsal .lt. 0.0 .or. zsal .gt. 45.0 ) then |
---|
722 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: S WARNING 2D, ', & |
---|
723 | tsb(ji,jj,jk,jp_sal), tsn(ji,jj,jk,jp_sal), ' at (', & |
---|
724 | ji, ',', jj, ',', jk, ') at time', kt |
---|
725 | endif |
---|
726 | # else |
---|
727 | zdtc = zdet * xthetad !! implicit detrital carbon |
---|
728 | # endif |
---|
729 | # if defined key_debug_medusa |
---|
730 | if (idf.eq.1) then |
---|
731 | !! AXY (15/01/10) |
---|
732 | if (trn(ji,jj,jk,jpdin).lt.0.) then |
---|
733 | IF (lwp) write (numout,*) '------------------------------' |
---|
734 | IF (lwp) write (numout,*) 'NEGATIVE DIN ERROR =', trn(ji,jj,jk,jpdin) |
---|
735 | IF (lwp) write (numout,*) 'NEGATIVE DIN ERROR @', ji, jj, jk, kt |
---|
736 | endif |
---|
737 | if (trn(ji,jj,jk,jpsil).lt.0.) then |
---|
738 | IF (lwp) write (numout,*) '------------------------------' |
---|
739 | IF (lwp) write (numout,*) 'NEGATIVE SIL ERROR =', trn(ji,jj,jk,jpsil) |
---|
740 | IF (lwp) write (numout,*) 'NEGATIVE SIL ERROR @', ji, jj, jk, kt |
---|
741 | endif |
---|
742 | # if defined key_roam |
---|
743 | if (trn(ji,jj,jk,jpdic).lt.0.) then |
---|
744 | IF (lwp) write (numout,*) '------------------------------' |
---|
745 | IF (lwp) write (numout,*) 'NEGATIVE DIC ERROR =', trn(ji,jj,jk,jpdic) |
---|
746 | IF (lwp) write (numout,*) 'NEGATIVE DIC ERROR @', ji, jj, jk, kt |
---|
747 | endif |
---|
748 | if (trn(ji,jj,jk,jpalk).lt.0.) then |
---|
749 | IF (lwp) write (numout,*) '------------------------------' |
---|
750 | IF (lwp) write (numout,*) 'NEGATIVE ALK ERROR =', trn(ji,jj,jk,jpalk) |
---|
751 | IF (lwp) write (numout,*) 'NEGATIVE ALK ERROR @', ji, jj, jk, kt |
---|
752 | endif |
---|
753 | if (trn(ji,jj,jk,jpoxy).lt.0.) then |
---|
754 | IF (lwp) write (numout,*) '------------------------------' |
---|
755 | IF (lwp) write (numout,*) 'NEGATIVE OXY ERROR =', trn(ji,jj,jk,jpoxy) |
---|
756 | IF (lwp) write (numout,*) 'NEGATIVE OXY ERROR @', ji, jj, jk, kt |
---|
757 | endif |
---|
758 | # endif |
---|
759 | endif |
---|
760 | # endif |
---|
761 | # if defined key_debug_medusa |
---|
762 | !! report state variable values |
---|
763 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
764 | IF (lwp) write (numout,*) '------------------------------' |
---|
765 | IF (lwp) write (numout,*) 'fthk(',jk,') = ', fthk |
---|
766 | IF (lwp) write (numout,*) 'zphn(',jk,') = ', zphn |
---|
767 | IF (lwp) write (numout,*) 'zphd(',jk,') = ', zphd |
---|
768 | IF (lwp) write (numout,*) 'zpds(',jk,') = ', zpds |
---|
769 | IF (lwp) write (numout,*) 'zzmi(',jk,') = ', zzmi |
---|
770 | IF (lwp) write (numout,*) 'zzme(',jk,') = ', zzme |
---|
771 | IF (lwp) write (numout,*) 'zdet(',jk,') = ', zdet |
---|
772 | IF (lwp) write (numout,*) 'zdin(',jk,') = ', zdin |
---|
773 | IF (lwp) write (numout,*) 'zsil(',jk,') = ', zsil |
---|
774 | IF (lwp) write (numout,*) 'zfer(',jk,') = ', zfer |
---|
775 | # if defined key_roam |
---|
776 | IF (lwp) write (numout,*) 'zdtc(',jk,') = ', zdtc |
---|
777 | IF (lwp) write (numout,*) 'zdic(',jk,') = ', zdic |
---|
778 | IF (lwp) write (numout,*) 'zalk(',jk,') = ', zalk |
---|
779 | IF (lwp) write (numout,*) 'zoxy(',jk,') = ', zoxy |
---|
780 | # endif |
---|
781 | endif |
---|
782 | # endif |
---|
783 | |
---|
784 | # if defined key_debug_medusa |
---|
785 | if (idf.eq.1.AND.idfval.eq.1.AND.jk.eq.1) then |
---|
786 | IF (lwp) write (numout,*) '------------------------------' |
---|
787 | IF (lwp) write (numout,*) 'dustmo(1) = ', dustmo(ji,jj,1) |
---|
788 | IF (lwp) write (numout,*) 'dustmo(2) = ', dustmo(ji,jj,2) |
---|
789 | IF (lwp) write (numout,*) 'dust = ', dust(ji,jj) |
---|
790 | endif |
---|
791 | # endif |
---|
792 | |
---|
793 | !! sum tracers for inventory checks |
---|
794 | ftot_n = fthk * ( zphn + zphd + zzmi + zzme + zdet + zdin ) |
---|
795 | ftot_si = fthk * ( zpds + zsil ) |
---|
796 | ftot_fe = fthk * ( xrfn * ( zphn + zphd + zzmi + zzme + zdet ) + zfer ) |
---|
797 | # if defined key_roam |
---|
798 | ftot_c = fthk * ( (xthetapn * zphn) + (xthetapd * zphd) + & |
---|
799 | (xthetazmi * zzmi) + (xthetazme * zzme) + zdtc + & |
---|
800 | zdic ) |
---|
801 | ftot_a = fthk * ( zalk ) |
---|
802 | ftot_o2 = fthk * ( zoxy ) |
---|
803 | # endif |
---|
804 | CALL flush(numout) |
---|
805 | |
---|
806 | !!====================================================================== |
---|
807 | !! LOCAL GRID CELL CALCULATIONS |
---|
808 | !!====================================================================== |
---|
809 | !! |
---|
810 | # if defined key_roam |
---|
811 | if ( jk .eq. 1 ) then |
---|
812 | !!---------------------------------------------------------------------- |
---|
813 | !! Air-sea gas exchange |
---|
814 | !!---------------------------------------------------------------------- |
---|
815 | !! |
---|
816 | !! a bit of set up ... |
---|
817 | ! f_uwind = zwnd_i(ji,jj) |
---|
818 | ! f_vwind = zwnd_j(ji,jj) |
---|
819 | !! AXY (17/07/14): zwind_i and zwind_j do not exist in this |
---|
820 | !! version of NEMO because it does not include |
---|
821 | !! the SBC changes that our local version has |
---|
822 | !! for accessing the HadGEM2 forcing; they |
---|
823 | !! could be added, but an alternative approach |
---|
824 | !! is to make use of wndm from oce_trc.F90 |
---|
825 | !! which is wind speed at 10m (which is what |
---|
826 | !! is required here; this may need to be |
---|
827 | !! revisited when MEDUSA properly interacts |
---|
828 | !! with UKESM1 physics |
---|
829 | ! f_uwind = zwind_i(ji,jj) |
---|
830 | ! f_vwind = zwind_j(ji,jj) |
---|
831 | ! f_wind = ((f_uwind**2.0) + (f_vwind**2.0))**0.5 |
---|
832 | f_wind = wndm(ji,jj) |
---|
833 | !! AXY (17/07/14): the current oxygen code takes in separate |
---|
834 | !! U and V components of the wind; to avoid |
---|
835 | !! the need to change this, calculate these |
---|
836 | !! components based on wndm; again, this is |
---|
837 | !! not ideal, but should suffice as a |
---|
838 | !! temporary measure; in the long-term all |
---|
839 | !! of MEDUSA's air-sea gas exchange terms |
---|
840 | !! will be revisited to ensure that they are |
---|
841 | !! valid and self-consistent; and the CO2 |
---|
842 | !! code will be wholly replaced with a more |
---|
843 | !! up-to-date parameterisation |
---|
844 | f_uwind = ((f_wind**2.0) / 2.0)**0.5 |
---|
845 | f_vwind = f_uwind |
---|
846 | f_pp0 = 1.0 |
---|
847 | !! IF(lwp) WRITE(numout,*) ' MEDUSA ztmp =', ztmp |
---|
848 | !! IF(lwp) WRITE(numout,*) ' MEDUSA zwind_i =', zwind_i(ji,jj) |
---|
849 | !! IF(lwp) WRITE(numout,*) ' MEDUSA zwind_j =', zwind_j(ji,jj) |
---|
850 | !! IF(lwp) WRITE(numout,*) ' MEDUSA f_wind =', f_wind |
---|
851 | !! IF(lwp) WRITE(numout,*) ' MEDUSA fr_i =', fr_i(ji,jj) |
---|
852 | !! |
---|
853 | # if defined key_axy_carbchem |
---|
854 | iters = 0 |
---|
855 | !! |
---|
856 | !! carbon dioxide (CO2); Jerry Blackford code (ostensibly OCMIP-2, but not) |
---|
857 | CALL trc_co2_medusa( ztmp, zsal, zdic, zalk, 0.0, f_wind, f_pco2a, & ! inputs |
---|
858 | f_ph, f_pco2w, f_h2co3, f_hco3, f_co3, f_omcal(ji,jj), & ! outputs |
---|
859 | f_omarg(ji,jj), f_co2flux, f_TDIC, f_TALK, f_dcf, f_henry, iters ) ! outputs |
---|
860 | !! |
---|
861 | !! AXY (09/01/14): removed iteration and NaN checks; these have |
---|
862 | !! been moved to trc_co2_medusa together with a |
---|
863 | !! fudge that amends erroneous values (this is |
---|
864 | !! intended to be a temporary fudge!); the |
---|
865 | !! output warnings are retained here so that |
---|
866 | !! failure position can be determined |
---|
867 | if (iters .eq. 25) then |
---|
868 | IF(lwp) WRITE(numout,*) ' trc_bio_medusa: ITERS WARNING, ', & |
---|
869 | iters, ' AT (', ji, ', ', jj, ', ', jk, ') AT ', kt |
---|
870 | endif |
---|
871 | # else |
---|
872 | !! AXY (18/04/13): switch off carbonate chemistry calculations; provide |
---|
873 | !! quasi-sensible alternatives |
---|
874 | f_ph = 8.1 |
---|
875 | f_pco2w = f_pco2a |
---|
876 | f_h2co3 = 0.005 * zdic |
---|
877 | f_hco3 = 0.865 * zdic |
---|
878 | f_co3 = 0.130 * zdic |
---|
879 | f_omcal(ji,jj) = 4. |
---|
880 | f_omarg(ji,jj) = 2. |
---|
881 | f_co2flux = 0. |
---|
882 | f_TDIC = zdic |
---|
883 | f_TALK = zalk |
---|
884 | f_dcf = 1. |
---|
885 | f_henry = 1. |
---|
886 | # endif |
---|
887 | !! |
---|
888 | !! already in right units; correct for sea-ice; divide through by layer thickness |
---|
889 | f_co2flux = (1. - fr_i(ji,jj)) * f_co2flux / fthk |
---|
890 | !! |
---|
891 | !! oxygen (O2); OCMIP-2 code |
---|
892 | CALL trc_oxy_medusa( ztmp, zsal, f_uwind, f_vwind, f_pp0, zoxy / 1000., fthk, & ! inputs |
---|
893 | f_kw660, f_o2flux, f_o2sat ) ! outputs |
---|
894 | !! |
---|
895 | !! mol/m3/s -> mmol/m3/d; correct for sea-ice |
---|
896 | f_o2flux = (1. - fr_i(ji,jj)) * f_o2flux * 1000. * 60. * 60. * 24. |
---|
897 | f_o2sat = f_o2sat * 1000. |
---|
898 | !! |
---|
899 | !! Jpalm (08-2014) |
---|
900 | !! DMS surface concentration calculation |
---|
901 | !! initialy added for UKESM1 model. |
---|
902 | !! using MET-OFFICE subroutine. |
---|
903 | !! DMS module only needs Chl concentration and MLD |
---|
904 | !! to get an aproximate value of DMS concentration. |
---|
905 | !! air-sea fluxes are calculated by atmospheric chemitry model |
---|
906 | !! from atm and oc-surface concentrations. |
---|
907 | !! |
---|
908 | !! AXY (13/03/15): this is amended to calculate all of the DMS |
---|
909 | !! estimates examined during UKESM1 (see comments |
---|
910 | !! in trcdms_medusa.F90) |
---|
911 | !! |
---|
912 | IF (jdms .eq. 1) THEN |
---|
913 | !! |
---|
914 | !! CALL trc_dms_medusa( zchn, zchd, hmld(ji,jj), & !! inputs |
---|
915 | !! dms_surf ) !! outputs |
---|
916 | CALL trc_dms_medusa( zchn, zchd, hmld(ji,jj), qsr(ji,jj), zdin, & !! inputs |
---|
917 | dms_surf, dms_andr, dms_simo, dms_aran, dms_hall ) !! outputs |
---|
918 | ENDIF |
---|
919 | !! End DMS Loop |
---|
920 | endif |
---|
921 | !! End jk = 1 loop within ROAM key |
---|
922 | # endif |
---|
923 | |
---|
924 | if ( jk .eq. 1 ) then |
---|
925 | !!---------------------------------------------------------------------- |
---|
926 | !! River inputs |
---|
927 | !!---------------------------------------------------------------------- |
---|
928 | !! |
---|
929 | !! runoff comes in as kg / m2 / s |
---|
930 | !! used and written out as m3 / m2 / d (= m / d) |
---|
931 | !! where 1000 kg / m2 / d = 1 m3 / m2 / d = 1 m / d |
---|
932 | !! |
---|
933 | !! AXY (17/07/14): the compiler doesn't like this line for some reason; |
---|
934 | !! as MEDUSA doesn't even use runoff for riverine inputs, |
---|
935 | !! a temporary solution is to switch off runoff entirely |
---|
936 | !! here; again, this change is one of several that will |
---|
937 | !! need revisiting once MEDUSA has bedded down in UKESM1; |
---|
938 | !! particularly so if the land scheme provides information |
---|
939 | !! concerning nutrient fluxes |
---|
940 | !! |
---|
941 | !! f_runoff(ji,jj) = sf_rnf(1)%fnow(ji,jj,1) / 1000. * 60. * 60. * 24. |
---|
942 | f_runoff(ji,jj) = 0.0 |
---|
943 | !! |
---|
944 | !! nutrients are added via rivers to the model in one of two ways: |
---|
945 | !! 1. via river concentration; i.e. the average nutrient concentration |
---|
946 | !! of a river water is described by a spatial file, and this is |
---|
947 | !! multiplied by runoff to give a nutrient flux |
---|
948 | !! 2. via direct river flux; i.e. the average nutrient flux due to |
---|
949 | !! rivers is described by a spatial file, and this is simply applied |
---|
950 | !! as a direct nutrient flux (i.e. it does not relate or respond to |
---|
951 | !! model runoff) |
---|
952 | !! nutrient fields are derived from the GlobalNEWS 2 database; carbon and |
---|
953 | !! alkalinity are derived from continent-scale DIC estimates (Huang et al., |
---|
954 | !! 2012) and some Arctic river alkalinity estimates (Katya?) |
---|
955 | !! |
---|
956 | !! as of 19/07/12, riverine nutrients can now be spread vertically across |
---|
957 | !! several grid cells rather than just poured into the surface box; this |
---|
958 | !! block of code is still executed, however, to set up the total amounts |
---|
959 | !! of nutrient entering via rivers |
---|
960 | !! |
---|
961 | !! nitrogen |
---|
962 | if (jriver_n .eq. 1) then |
---|
963 | !! river concentration specified; use runoff to calculate input |
---|
964 | f_riv_n(ji,jj) = f_runoff(ji,jj) * riv_n(ji,jj) |
---|
965 | elseif (jriver_n .eq. 2) then |
---|
966 | !! river flux specified; independent of runoff |
---|
967 | f_riv_n(ji,jj) = riv_n(ji,jj) |
---|
968 | endif |
---|
969 | !! |
---|
970 | !! silicon |
---|
971 | if (jriver_si .eq. 1) then |
---|
972 | !! river concentration specified; use runoff to calculate input |
---|
973 | f_riv_si(ji,jj) = f_runoff(ji,jj) * riv_si(ji,jj) |
---|
974 | elseif (jriver_si .eq. 2) then |
---|
975 | !! river flux specified; independent of runoff |
---|
976 | f_riv_si(ji,jj) = riv_si(ji,jj) |
---|
977 | endif |
---|
978 | !! |
---|
979 | !! carbon |
---|
980 | if (jriver_c .eq. 1) then |
---|
981 | !! river concentration specified; use runoff to calculate input |
---|
982 | f_riv_c(ji,jj) = f_runoff(ji,jj) * riv_c(ji,jj) |
---|
983 | elseif (jriver_c .eq. 2) then |
---|
984 | !! river flux specified; independent of runoff |
---|
985 | f_riv_c(ji,jj) = riv_c(ji,jj) |
---|
986 | endif |
---|
987 | !! |
---|
988 | !! alkalinity |
---|
989 | if (jriver_alk .eq. 1) then |
---|
990 | !! river concentration specified; use runoff to calculate input |
---|
991 | f_riv_alk(ji,jj) = f_runoff(ji,jj) * riv_alk(ji,jj) |
---|
992 | elseif (jriver_alk .eq. 2) then |
---|
993 | !! river flux specified; independent of runoff |
---|
994 | f_riv_alk(ji,jj) = riv_alk(ji,jj) |
---|
995 | endif |
---|
996 | |
---|
997 | endif |
---|
998 | |
---|
999 | !!---------------------------------------------------------------------- |
---|
1000 | !! Chlorophyll calculations |
---|
1001 | !!---------------------------------------------------------------------- |
---|
1002 | !! |
---|
1003 | !! non-diatoms |
---|
1004 | if (zphn.GT.rsmall) then |
---|
1005 | fthetan = max(tiny(zchn), (zchn * xxi) / (zphn + tiny(zphn))) |
---|
1006 | faln = xaln * fthetan |
---|
1007 | else |
---|
1008 | fthetan = 0. |
---|
1009 | faln = 0. |
---|
1010 | endif |
---|
1011 | !! |
---|
1012 | !! diatoms |
---|
1013 | if (zphd.GT.rsmall) then |
---|
1014 | fthetad = max(tiny(zchd), (zchd * xxi) / (zphd + tiny(zphd))) |
---|
1015 | fald = xald * fthetad |
---|
1016 | else |
---|
1017 | fthetad = 0. |
---|
1018 | fald = 0. |
---|
1019 | endif |
---|
1020 | |
---|
1021 | # if defined key_debug_medusa |
---|
1022 | !! report biological calculations |
---|
1023 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1024 | IF (lwp) write (numout,*) '------------------------------' |
---|
1025 | IF (lwp) write (numout,*) 'faln(',jk,') = ', faln |
---|
1026 | IF (lwp) write (numout,*) 'fald(',jk,') = ', fald |
---|
1027 | endif |
---|
1028 | # endif |
---|
1029 | |
---|
1030 | !!---------------------------------------------------------------------- |
---|
1031 | !! Phytoplankton light limitation |
---|
1032 | !!---------------------------------------------------------------------- |
---|
1033 | !! |
---|
1034 | !! It is assumed xpar is the depth-averaged (vertical layer) PAR |
---|
1035 | !! Light limitation (check self-shading) in W/m2 |
---|
1036 | !! |
---|
1037 | !! Note that there is no temperature dependence in phytoplankton |
---|
1038 | !! growth rate or any other function. |
---|
1039 | !! In calculation of Chl/Phy ratio tiny(phyto) is introduced to avoid |
---|
1040 | !! NaNs in case of Phy==0. |
---|
1041 | !! |
---|
1042 | !! fthetad and fthetan are Chl:C ratio (gChl/gC) in diat and non-diat: |
---|
1043 | !! for 1:1 Chl:P ratio (mgChl/mmolN) theta=0.012 |
---|
1044 | !! |
---|
1045 | !! AXY (16/07/09) |
---|
1046 | !! temperature for new Eppley style phytoplankton growth |
---|
1047 | loc_T = tsn(ji,jj,jk,jp_tem) |
---|
1048 | fun_T = 1.066**(1.0 * loc_T) |
---|
1049 | if (jphy.eq.1) then |
---|
1050 | xvpnT = xvpn * fun_T |
---|
1051 | xvpdT = xvpd * fun_T |
---|
1052 | else |
---|
1053 | xvpnT = xvpn |
---|
1054 | xvpdT = xvpd |
---|
1055 | endif |
---|
1056 | !! |
---|
1057 | !! non-diatoms |
---|
1058 | fchn1 = (xvpnT * xvpnT) + (faln * faln * xpar(ji,jj,jk) * xpar(ji,jj,jk)) |
---|
1059 | if (fchn1.GT.rsmall) then |
---|
1060 | fchn = xvpnT / (sqrt(fchn1) + tiny(fchn1)) |
---|
1061 | else |
---|
1062 | fchn = 0. |
---|
1063 | endif |
---|
1064 | fjln = fchn * faln * xpar(ji,jj,jk) !! non-diatom J term |
---|
1065 | !! |
---|
1066 | !! diatoms |
---|
1067 | fchd1 = (xvpdT * xvpdT) + (fald * fald * xpar(ji,jj,jk) * xpar(ji,jj,jk)) |
---|
1068 | if (fchd1.GT.rsmall) then |
---|
1069 | fchd = xvpdT / (sqrt(fchd1) + tiny(fchd1)) |
---|
1070 | else |
---|
1071 | fchd = 0. |
---|
1072 | endif |
---|
1073 | fjld = fchd * fald * xpar(ji,jj,jk) !! diatom J term |
---|
1074 | |
---|
1075 | # if defined key_debug_medusa |
---|
1076 | !! report phytoplankton light limitation |
---|
1077 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1078 | IF (lwp) write (numout,*) '------------------------------' |
---|
1079 | IF (lwp) write (numout,*) 'fchn(',jk,') = ', fchn |
---|
1080 | IF (lwp) write (numout,*) 'fchd(',jk,') = ', fchd |
---|
1081 | IF (lwp) write (numout,*) 'fjln(',jk,') = ', fjln |
---|
1082 | IF (lwp) write (numout,*) 'fjld(',jk,') = ', fjld |
---|
1083 | endif |
---|
1084 | # endif |
---|
1085 | |
---|
1086 | !!---------------------------------------------------------------------- |
---|
1087 | !! Phytoplankton nutrient limitation |
---|
1088 | !!---------------------------------------------------------------------- |
---|
1089 | !! |
---|
1090 | !! non-diatoms (N, Fe) |
---|
1091 | fnln = zdin / (zdin + xnln) !! non-diatom Qn term |
---|
1092 | ffln = zfer / (zfer + xfln) !! non-diatom Qf term |
---|
1093 | !! |
---|
1094 | !! diatoms (N, Si, Fe) |
---|
1095 | fnld = zdin / (zdin + xnld) !! diatom Qn term |
---|
1096 | fsld = zsil / (zsil + xsld) !! diatom Qs term |
---|
1097 | ffld = zfer / (zfer + xfld) !! diatom Qf term |
---|
1098 | |
---|
1099 | # if defined key_debug_medusa |
---|
1100 | !! report phytoplankton nutrient limitation |
---|
1101 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1102 | IF (lwp) write (numout,*) '------------------------------' |
---|
1103 | IF (lwp) write (numout,*) 'fnln(',jk,') = ', fnln |
---|
1104 | IF (lwp) write (numout,*) 'fnld(',jk,') = ', fnld |
---|
1105 | IF (lwp) write (numout,*) 'ffln(',jk,') = ', ffln |
---|
1106 | IF (lwp) write (numout,*) 'ffld(',jk,') = ', ffld |
---|
1107 | IF (lwp) write (numout,*) 'fsld(',jk,') = ', fsld |
---|
1108 | endif |
---|
1109 | # endif |
---|
1110 | |
---|
1111 | !!---------------------------------------------------------------------- |
---|
1112 | !! Primary production (non-diatoms) |
---|
1113 | !! (note: still needs multiplying by phytoplankton concentration) |
---|
1114 | !!---------------------------------------------------------------------- |
---|
1115 | !! |
---|
1116 | if (jliebig .eq. 0) then |
---|
1117 | !! multiplicative nutrient limitation |
---|
1118 | fpnlim = fnln * ffln |
---|
1119 | elseif (jliebig .eq. 1) then |
---|
1120 | !! Liebig Law (= most limiting) nutrient limitation |
---|
1121 | fpnlim = min(fnln, ffln) |
---|
1122 | endif |
---|
1123 | fprn = fjln * fpnlim |
---|
1124 | |
---|
1125 | !!---------------------------------------------------------------------- |
---|
1126 | !! Primary production (diatoms) |
---|
1127 | !! (note: still needs multiplying by phytoplankton concentration) |
---|
1128 | !! |
---|
1129 | !! production here is split between nitrogen production and that of |
---|
1130 | !! silicon; depending upon the "intracellular" ratio of Si:N, model |
---|
1131 | !! diatoms will uptake nitrogen/silicon differentially; this borrows |
---|
1132 | !! from the diatom model of Mongin et al. (2006) |
---|
1133 | !!---------------------------------------------------------------------- |
---|
1134 | !! |
---|
1135 | if (jliebig .eq. 0) then |
---|
1136 | !! multiplicative nutrient limitation |
---|
1137 | fpdlim = fnld * ffld |
---|
1138 | elseif (jliebig .eq. 1) then |
---|
1139 | !! Liebig Law (= most limiting) nutrient limitation |
---|
1140 | fpdlim = min(fnld, ffld) |
---|
1141 | endif |
---|
1142 | !! |
---|
1143 | if (zphd.GT.rsmall .AND. zpds.GT.rsmall) then |
---|
1144 | !! "intracellular" elemental ratios |
---|
1145 | ! fsin = zpds / (zphd + tiny(zphd)) |
---|
1146 | ! fnsi = zphd / (zpds + tiny(zpds)) |
---|
1147 | fsin = 0.0 |
---|
1148 | IF( zphd .GT. rsmall) fsin = zpds / zphd |
---|
1149 | fnsi = 0.0 |
---|
1150 | IF( zpds .GT. rsmall) fnsi = zphd / zpds |
---|
1151 | !! AXY (23/02/10): these next variables derive from Mongin et al. (2003) |
---|
1152 | fsin1 = 3.0 * xsin0 !! = 0.6 |
---|
1153 | fnsi1 = 1.0 / fsin1 !! = 1.667 |
---|
1154 | fnsi2 = 1.0 / xsin0 !! = 5.0 |
---|
1155 | !! |
---|
1156 | !! conditionalities based on ratios |
---|
1157 | !! nitrogen (and iron and carbon) |
---|
1158 | if (fsin.le.xsin0) then |
---|
1159 | fprd = 0.0 |
---|
1160 | fsld2 = 0.0 |
---|
1161 | elseif (fsin.lt.fsin1) then |
---|
1162 | fprd = xuif * ((fsin - xsin0) / (fsin + tiny(fsin))) * (fjld * fpdlim) |
---|
1163 | fsld2 = xuif * ((fsin - xsin0) / (fsin + tiny(fsin))) |
---|
1164 | elseif (fsin.ge.fsin1) then |
---|
1165 | fprd = (fjld * fpdlim) |
---|
1166 | fsld2 = 1.0 |
---|
1167 | endif |
---|
1168 | !! |
---|
1169 | !! silicon |
---|
1170 | if (fsin.lt.fnsi1) then |
---|
1171 | fprds = (fjld * fsld) |
---|
1172 | elseif (fsin.lt.fnsi2) then |
---|
1173 | fprds = xuif * ((fnsi - xnsi0) / (fnsi + tiny(fnsi))) * (fjld * fsld) |
---|
1174 | else |
---|
1175 | fprds = 0.0 |
---|
1176 | endif |
---|
1177 | else |
---|
1178 | fsin = 0.0 |
---|
1179 | fnsi = 0.0 |
---|
1180 | fprd = 0.0 |
---|
1181 | fsld2 = 0.0 |
---|
1182 | fprds = 0.0 |
---|
1183 | endif |
---|
1184 | |
---|
1185 | # if defined key_debug_medusa |
---|
1186 | !! report phytoplankton growth (including diatom silicon submodel) |
---|
1187 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1188 | IF (lwp) write (numout,*) '------------------------------' |
---|
1189 | IF (lwp) write (numout,*) 'fsin(',jk,') = ', fsin |
---|
1190 | IF (lwp) write (numout,*) 'fnsi(',jk,') = ', fnsi |
---|
1191 | IF (lwp) write (numout,*) 'fsld2(',jk,') = ', fsld2 |
---|
1192 | IF (lwp) write (numout,*) 'fprn(',jk,') = ', fprn |
---|
1193 | IF (lwp) write (numout,*) 'fprd(',jk,') = ', fprd |
---|
1194 | IF (lwp) write (numout,*) 'fprds(',jk,') = ', fprds |
---|
1195 | endif |
---|
1196 | # endif |
---|
1197 | |
---|
1198 | !!---------------------------------------------------------------------- |
---|
1199 | !! Mixed layer primary production |
---|
1200 | !! this block calculates the amount of primary production that occurs |
---|
1201 | !! within the upper mixed layer; this allows the separate diagnosis |
---|
1202 | !! of "sub-surface" primary production; it does assume that short- |
---|
1203 | !! term variability in mixed layer depth doesn't mess with things |
---|
1204 | !! though |
---|
1205 | !!---------------------------------------------------------------------- |
---|
1206 | !! |
---|
1207 | if (fdep1.le.hmld(ji,jj)) then |
---|
1208 | !! this level is entirely in the mixed layer |
---|
1209 | fq0 = 1.0 |
---|
1210 | elseif (fdep.ge.hmld(ji,jj)) then |
---|
1211 | !! this level is entirely below the mixed layer |
---|
1212 | fq0 = 0.0 |
---|
1213 | else |
---|
1214 | !! this level straddles the mixed layer |
---|
1215 | fq0 = (hmld(ji,jj) - fdep) / fthk |
---|
1216 | endif |
---|
1217 | !! |
---|
1218 | fprn_ml = (fprn * zphn * fthk * fq0) |
---|
1219 | fprd_ml = (fprd * zphd * fthk * fq0) |
---|
1220 | |
---|
1221 | !!---------------------------------------------------------------------- |
---|
1222 | !! More chlorophyll calculations |
---|
1223 | !!---------------------------------------------------------------------- |
---|
1224 | !! |
---|
1225 | !! frn = (xthetam / fthetan) * (fprn / (fthetan * xpar(ji,jj,jk))) |
---|
1226 | !! frd = (xthetam / fthetad) * (fprd / (fthetad * xpar(ji,jj,jk))) |
---|
1227 | frn = (xthetam * fchn * fnln * ffln ) / (fthetan + tiny(fthetan)) |
---|
1228 | !! AXY (12/05/09): there's potentially a problem here; fsld, silicic acid |
---|
1229 | !! limitation, is used in the following line to regulate chlorophyll |
---|
1230 | !! growth in a manner that is inconsistent with its use in the regulation |
---|
1231 | !! of biomass growth; the Mongin term term used in growth is more complex |
---|
1232 | !! than the simple multiplicative function used below |
---|
1233 | !! frd = (xthetam * fchd * fnld * ffld * fsld) / (fthetad + tiny(fthetad)) |
---|
1234 | !! AXY (12/05/09): this replacement line uses the new variable, fsld2, to |
---|
1235 | !! regulate chlorophyll growth |
---|
1236 | frd = (xthetamd * fchd * fnld * ffld * fsld2) / (fthetad + tiny(fthetad)) |
---|
1237 | |
---|
1238 | # if defined key_debug_medusa |
---|
1239 | !! report chlorophyll calculations |
---|
1240 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1241 | IF (lwp) write (numout,*) '------------------------------' |
---|
1242 | IF (lwp) write (numout,*) 'fthetan(',jk,') = ', fthetan |
---|
1243 | IF (lwp) write (numout,*) 'fthetad(',jk,') = ', fthetad |
---|
1244 | IF (lwp) write (numout,*) 'frn(',jk,') = ', frn |
---|
1245 | IF (lwp) write (numout,*) 'frd(',jk,') = ', frd |
---|
1246 | endif |
---|
1247 | # endif |
---|
1248 | |
---|
1249 | !!---------------------------------------------------------------------- |
---|
1250 | !! Zooplankton Grazing |
---|
1251 | !! this code supplements the base grazing model with one that |
---|
1252 | !! considers the C:N ratio of grazed food and balances this against |
---|
1253 | !! the requirements of zooplankton growth; this model is derived |
---|
1254 | !! from that of Anderson & Pondaven (2003) |
---|
1255 | !! |
---|
1256 | !! the current version of the code assumes a fixed C:N ratio for |
---|
1257 | !! detritus (in contrast to Anderson & Pondaven, 2003), though the |
---|
1258 | !! full equations are retained for future extension |
---|
1259 | !!---------------------------------------------------------------------- |
---|
1260 | !! |
---|
1261 | !!---------------------------------------------------------------------- |
---|
1262 | !! Microzooplankton first |
---|
1263 | !!---------------------------------------------------------------------- |
---|
1264 | !! |
---|
1265 | fmi1 = (xkmi * xkmi) + (xpmipn * zphn * zphn) + (xpmid * zdet * zdet) |
---|
1266 | fmi = xgmi * zzmi / fmi1 |
---|
1267 | fgmipn = fmi * xpmipn * zphn * zphn !! grazing on non-diatoms |
---|
1268 | fgmid = fmi * xpmid * zdet * zdet !! grazing on detrital nitrogen |
---|
1269 | # if defined key_roam |
---|
1270 | fgmidc = rsmall !acc |
---|
1271 | IF ( zdet .GT. rsmall ) fgmidc = (zdtc / (zdet + tiny(zdet))) * fgmid !! grazing on detrital carbon |
---|
1272 | # else |
---|
1273 | !! AXY (26/11/08): implicit detrital carbon change |
---|
1274 | fgmidc = xthetad * fgmid !! grazing on detrital carbon |
---|
1275 | # endif |
---|
1276 | !! |
---|
1277 | !! which translates to these incoming N and C fluxes |
---|
1278 | finmi = (1.0 - xphi) * (fgmipn + fgmid) |
---|
1279 | ficmi = (1.0 - xphi) * ((xthetapn * fgmipn) + fgmidc) |
---|
1280 | !! |
---|
1281 | !! the ideal food C:N ratio for microzooplankton |
---|
1282 | !! xbetan = 0.77; xthetaz = 5.625; xbetac = 0.64; xkc = 0.80 |
---|
1283 | fstarmi = (xbetan * xthetazmi) / (xbetac * xkc) |
---|
1284 | !! |
---|
1285 | !! process these to determine proportioning of grazed N and C |
---|
1286 | !! (since there is no explicit consideration of respiration, |
---|
1287 | !! only growth and excretion are calculated here) |
---|
1288 | fmith = (ficmi / (finmi + tiny(finmi))) |
---|
1289 | if (fmith.ge.fstarmi) then |
---|
1290 | fmigrow = xbetan * finmi |
---|
1291 | fmiexcr = 0.0 |
---|
1292 | else |
---|
1293 | fmigrow = (xbetac * xkc * ficmi) / xthetazmi |
---|
1294 | fmiexcr = ficmi * ((xbetan / (fmith + tiny(fmith))) - ((xbetac * xkc) / xthetazmi)) |
---|
1295 | endif |
---|
1296 | # if defined key_roam |
---|
1297 | fmiresp = (xbetac * ficmi) - (xthetazmi * fmigrow) |
---|
1298 | # endif |
---|
1299 | |
---|
1300 | # if defined key_debug_medusa |
---|
1301 | !! report microzooplankton grazing |
---|
1302 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1303 | IF (lwp) write (numout,*) '------------------------------' |
---|
1304 | IF (lwp) write (numout,*) 'fmi1(',jk,') = ', fmi1 |
---|
1305 | IF (lwp) write (numout,*) 'fmi(',jk,') = ', fmi |
---|
1306 | IF (lwp) write (numout,*) 'fgmipn(',jk,') = ', fgmipn |
---|
1307 | IF (lwp) write (numout,*) 'fgmid(',jk,') = ', fgmid |
---|
1308 | IF (lwp) write (numout,*) 'fgmidc(',jk,') = ', fgmidc |
---|
1309 | IF (lwp) write (numout,*) 'finmi(',jk,') = ', finmi |
---|
1310 | IF (lwp) write (numout,*) 'ficmi(',jk,') = ', ficmi |
---|
1311 | IF (lwp) write (numout,*) 'fstarmi(',jk,') = ', fstarmi |
---|
1312 | IF (lwp) write (numout,*) 'fmith(',jk,') = ', fmith |
---|
1313 | IF (lwp) write (numout,*) 'fmigrow(',jk,') = ', fmigrow |
---|
1314 | IF (lwp) write (numout,*) 'fmiexcr(',jk,') = ', fmiexcr |
---|
1315 | # if defined key_roam |
---|
1316 | IF (lwp) write (numout,*) 'fmiresp(',jk,') = ', fmiresp |
---|
1317 | # endif |
---|
1318 | endif |
---|
1319 | # endif |
---|
1320 | |
---|
1321 | !!---------------------------------------------------------------------- |
---|
1322 | !! Mesozooplankton second |
---|
1323 | !!---------------------------------------------------------------------- |
---|
1324 | !! |
---|
1325 | fme1 = (xkme * xkme) + (xpmepn * zphn * zphn) + (xpmepd * zphd * zphd) + & |
---|
1326 | (xpmezmi * zzmi * zzmi) + (xpmed * zdet * zdet) |
---|
1327 | fme = xgme * zzme / fme1 |
---|
1328 | fgmepn = fme * xpmepn * zphn * zphn !! grazing on non-diatoms |
---|
1329 | fgmepd = fme * xpmepd * zphd * zphd !! grazing on diatoms |
---|
1330 | fgmepds = fsin * fgmepd !! grazing on diatom silicon |
---|
1331 | fgmezmi = fme * xpmezmi * zzmi * zzmi !! grazing on microzooplankton |
---|
1332 | fgmed = fme * xpmed * zdet * zdet !! grazing on detrital nitrogen |
---|
1333 | # if defined key_roam |
---|
1334 | fgmedc = rsmall !acc |
---|
1335 | IF ( zdet .GT. rsmall ) fgmedc = (zdtc / (zdet + tiny(zdet))) * fgmed !! grazing on detrital carbon |
---|
1336 | # else |
---|
1337 | !! AXY (26/11/08): implicit detrital carbon change |
---|
1338 | fgmedc = xthetad * fgmed !! grazing on detrital carbon |
---|
1339 | # endif |
---|
1340 | !! |
---|
1341 | !! which translates to these incoming N and C fluxes |
---|
1342 | finme = (1.0 - xphi) * (fgmepn + fgmepd + fgmezmi + fgmed) |
---|
1343 | ficme = (1.0 - xphi) * ((xthetapn * fgmepn) + (xthetapd * fgmepd) + & |
---|
1344 | (xthetazmi * fgmezmi) + fgmedc) |
---|
1345 | !! |
---|
1346 | !! the ideal food C:N ratio for mesozooplankton |
---|
1347 | !! xbetan = 0.77; xthetaz = 5.625; xbetac = 0.64; xkc = 0.80 |
---|
1348 | fstarme = (xbetan * xthetazme) / (xbetac * xkc) |
---|
1349 | !! |
---|
1350 | !! process these to determine proportioning of grazed N and C |
---|
1351 | !! (since there is no explicit consideration of respiration, |
---|
1352 | !! only growth and excretion are calculated here) |
---|
1353 | fmeth = (ficme / (finme + tiny(finme))) |
---|
1354 | if (fmeth.ge.fstarme) then |
---|
1355 | fmegrow = xbetan * finme |
---|
1356 | fmeexcr = 0.0 |
---|
1357 | else |
---|
1358 | fmegrow = (xbetac * xkc * ficme) / xthetazme |
---|
1359 | fmeexcr = ficme * ((xbetan / (fmeth + tiny(fmeth))) - ((xbetac * xkc) / xthetazme)) |
---|
1360 | endif |
---|
1361 | # if defined key_roam |
---|
1362 | fmeresp = (xbetac * ficme) - (xthetazme * fmegrow) |
---|
1363 | # endif |
---|
1364 | |
---|
1365 | # if defined key_debug_medusa |
---|
1366 | !! report mesozooplankton grazing |
---|
1367 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1368 | IF (lwp) write (numout,*) '------------------------------' |
---|
1369 | IF (lwp) write (numout,*) 'fme1(',jk,') = ', fme1 |
---|
1370 | IF (lwp) write (numout,*) 'fme(',jk,') = ', fme |
---|
1371 | IF (lwp) write (numout,*) 'fgmepn(',jk,') = ', fgmepn |
---|
1372 | IF (lwp) write (numout,*) 'fgmepd(',jk,') = ', fgmepd |
---|
1373 | IF (lwp) write (numout,*) 'fgmepds(',jk,') = ', fgmepds |
---|
1374 | IF (lwp) write (numout,*) 'fgmezmi(',jk,') = ', fgmezmi |
---|
1375 | IF (lwp) write (numout,*) 'fgmed(',jk,') = ', fgmed |
---|
1376 | IF (lwp) write (numout,*) 'fgmedc(',jk,') = ', fgmedc |
---|
1377 | IF (lwp) write (numout,*) 'finme(',jk,') = ', finme |
---|
1378 | IF (lwp) write (numout,*) 'ficme(',jk,') = ', ficme |
---|
1379 | IF (lwp) write (numout,*) 'fstarme(',jk,') = ', fstarme |
---|
1380 | IF (lwp) write (numout,*) 'fmeth(',jk,') = ', fmeth |
---|
1381 | IF (lwp) write (numout,*) 'fmegrow(',jk,') = ', fmegrow |
---|
1382 | IF (lwp) write (numout,*) 'fmeexcr(',jk,') = ', fmeexcr |
---|
1383 | # if defined key_roam |
---|
1384 | IF (lwp) write (numout,*) 'fmeresp(',jk,') = ', fmeresp |
---|
1385 | # endif |
---|
1386 | endif |
---|
1387 | # endif |
---|
1388 | |
---|
1389 | fzmi_i(ji,jj) = fzmi_i(ji,jj) + fthk * ( & |
---|
1390 | fgmipn + fgmid ) |
---|
1391 | fzmi_o(ji,jj) = fzmi_o(ji,jj) + fthk * ( & |
---|
1392 | fmigrow + (xphi * (fgmipn + fgmid)) + fmiexcr + ((1.0 - xbetan) * finmi) ) |
---|
1393 | fzme_i(ji,jj) = fzme_i(ji,jj) + fthk * ( & |
---|
1394 | fgmepn + fgmepd + fgmezmi + fgmed ) |
---|
1395 | fzme_o(ji,jj) = fzme_o(ji,jj) + fthk * ( & |
---|
1396 | fmegrow + (xphi * (fgmepn + fgmepd + fgmezmi + fgmed)) + fmeexcr + ((1.0 - xbetan) * finme) ) |
---|
1397 | |
---|
1398 | !!---------------------------------------------------------------------- |
---|
1399 | !! Plankton metabolic losses |
---|
1400 | !! Linear loss processes assumed to be metabolic in origin |
---|
1401 | !!---------------------------------------------------------------------- |
---|
1402 | !! |
---|
1403 | fdpn2 = xmetapn * zphn |
---|
1404 | fdpd2 = xmetapd * zphd |
---|
1405 | fdpds2 = xmetapd * zpds |
---|
1406 | fdzmi2 = xmetazmi * zzmi |
---|
1407 | fdzme2 = xmetazme * zzme |
---|
1408 | |
---|
1409 | !!---------------------------------------------------------------------- |
---|
1410 | !! Plankton mortality losses |
---|
1411 | !! EKP (26/02/09): phytoplankton hyperbolic mortality term introduced |
---|
1412 | !! to improve performance in gyres |
---|
1413 | !!---------------------------------------------------------------------- |
---|
1414 | !! |
---|
1415 | !! non-diatom phytoplankton |
---|
1416 | if (jmpn.eq.1) fdpn = xmpn * zphn !! linear |
---|
1417 | if (jmpn.eq.2) fdpn = xmpn * zphn * zphn !! quadratic |
---|
1418 | if (jmpn.eq.3) fdpn = xmpn * zphn * & !! hyperbolic |
---|
1419 | (zphn / (xkphn + zphn)) |
---|
1420 | if (jmpn.eq.4) fdpn = xmpn * zphn * & !! sigmoid |
---|
1421 | ((zphn * zphn) / (xkphn + (zphn * zphn))) |
---|
1422 | !! |
---|
1423 | !! diatom phytoplankton |
---|
1424 | if (jmpd.eq.1) fdpd = xmpd * zphd !! linear |
---|
1425 | if (jmpd.eq.2) fdpd = xmpd * zphd * zphd !! quadratic |
---|
1426 | if (jmpd.eq.3) fdpd = xmpd * zphd * & !! hyperbolic |
---|
1427 | (zphd / (xkphd + zphd)) |
---|
1428 | if (jmpd.eq.4) fdpd = xmpd * zphd * & !! sigmoid |
---|
1429 | ((zphd * zphd) / (xkphd + (zphd * zphd))) |
---|
1430 | fdpds = fdpd * fsin |
---|
1431 | !! |
---|
1432 | !! microzooplankton |
---|
1433 | if (jmzmi.eq.1) fdzmi = xmzmi * zzmi !! linear |
---|
1434 | if (jmzmi.eq.2) fdzmi = xmzmi * zzmi * zzmi !! quadratic |
---|
1435 | if (jmzmi.eq.3) fdzmi = xmzmi * zzmi * & !! hyperbolic |
---|
1436 | (zzmi / (xkzmi + zzmi)) |
---|
1437 | if (jmzmi.eq.4) fdzmi = xmzmi * zzmi * & !! sigmoid |
---|
1438 | ((zzmi * zzmi) / (xkzmi + (zzmi * zzmi))) |
---|
1439 | !! |
---|
1440 | !! mesozooplankton |
---|
1441 | if (jmzme.eq.1) fdzme = xmzme * zzme !! linear |
---|
1442 | if (jmzme.eq.2) fdzme = xmzme * zzme * zzme !! quadratic |
---|
1443 | if (jmzme.eq.3) fdzme = xmzme * zzme * & !! hyperbolic |
---|
1444 | (zzme / (xkzme + zzme)) |
---|
1445 | if (jmzme.eq.4) fdzme = xmzme * zzme * & !! sigmoid |
---|
1446 | ((zzme * zzme) / (xkzme + (zzme * zzme))) |
---|
1447 | |
---|
1448 | !!---------------------------------------------------------------------- |
---|
1449 | !! Detritus remineralisation |
---|
1450 | !! Constant or temperature-dependent |
---|
1451 | !!---------------------------------------------------------------------- |
---|
1452 | !! |
---|
1453 | if (jmd.eq.1) then |
---|
1454 | !! temperature-dependent |
---|
1455 | fdd = xmd * fun_T * zdet |
---|
1456 | # if defined key_roam |
---|
1457 | fddc = xmdc * fun_T * zdtc |
---|
1458 | # endif |
---|
1459 | else |
---|
1460 | !! temperature-independent |
---|
1461 | fdd = xmd * zdet |
---|
1462 | # if defined key_roam |
---|
1463 | fddc = xmdc * zdtc |
---|
1464 | # endif |
---|
1465 | endif |
---|
1466 | !! |
---|
1467 | !! AXY (22/07/09): accelerate detrital remineralisation in the bottom box |
---|
1468 | if (jk.eq.(mbathy(ji,jj)-1) .and. jsfd.eq.1) then |
---|
1469 | fdd = 1.0 * zdet |
---|
1470 | # if defined key_roam |
---|
1471 | fddc = 1.0 * zdtc |
---|
1472 | # endif |
---|
1473 | endif |
---|
1474 | |
---|
1475 | # if defined key_debug_medusa |
---|
1476 | !! report plankton mortality and remineralisation |
---|
1477 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1478 | IF (lwp) write (numout,*) '------------------------------' |
---|
1479 | IF (lwp) write (numout,*) 'fdpn2(',jk,') = ', fdpn2 |
---|
1480 | IF (lwp) write (numout,*) 'fdpd2(',jk,') = ', fdpd2 |
---|
1481 | IF (lwp) write (numout,*) 'fdpds2(',jk,')= ', fdpds2 |
---|
1482 | IF (lwp) write (numout,*) 'fdzmi2(',jk,')= ', fdzmi2 |
---|
1483 | IF (lwp) write (numout,*) 'fdzme2(',jk,')= ', fdzme2 |
---|
1484 | IF (lwp) write (numout,*) 'fdpn(',jk,') = ', fdpn |
---|
1485 | IF (lwp) write (numout,*) 'fdpd(',jk,') = ', fdpd |
---|
1486 | IF (lwp) write (numout,*) 'fdpds(',jk,') = ', fdpds |
---|
1487 | IF (lwp) write (numout,*) 'fdzmi(',jk,') = ', fdzmi |
---|
1488 | IF (lwp) write (numout,*) 'fdzme(',jk,') = ', fdzme |
---|
1489 | IF (lwp) write (numout,*) 'fdd(',jk,') = ', fdd |
---|
1490 | # if defined key_roam |
---|
1491 | IF (lwp) write (numout,*) 'fddc(',jk,') = ', fddc |
---|
1492 | # endif |
---|
1493 | endif |
---|
1494 | # endif |
---|
1495 | |
---|
1496 | !!---------------------------------------------------------------------- |
---|
1497 | !! Detritus addition to benthos |
---|
1498 | !! If activated, slow detritus in the bottom box will enter the |
---|
1499 | !! benthic pool |
---|
1500 | !!---------------------------------------------------------------------- |
---|
1501 | !! |
---|
1502 | if (jk.eq.(mbathy(ji,jj)-1) .and. jorgben.eq.1) then |
---|
1503 | !! this is the BOTTOM OCEAN BOX -> into the benthic pool! |
---|
1504 | !! |
---|
1505 | f_sbenin_n(ji,jj) = (zdet * vsed * 86400.) |
---|
1506 | f_sbenin_fe(ji,jj) = (zdet * vsed * 86400. * xrfn) |
---|
1507 | # if defined key_roam |
---|
1508 | f_sbenin_c(ji,jj) = (zdtc * vsed * 86400.) |
---|
1509 | # else |
---|
1510 | f_sbenin_c(ji,jj) = (zdet * vsed * 86400. * xthetad) |
---|
1511 | # endif |
---|
1512 | endif |
---|
1513 | |
---|
1514 | !!---------------------------------------------------------------------- |
---|
1515 | !! Iron chemistry and fractionation |
---|
1516 | !! following the Parekh et al. (2004) scheme adopted by the Met. |
---|
1517 | !! Office, Medusa models total iron but considers "free" and |
---|
1518 | !! ligand-bound forms for the purposes of scavenging (only "free" |
---|
1519 | !! iron can be scavenged |
---|
1520 | !!---------------------------------------------------------------------- |
---|
1521 | !! |
---|
1522 | !! total iron concentration (mmol Fe / m3 -> umol Fe / m3) |
---|
1523 | xFeT = zfer * 1.e3 |
---|
1524 | !! |
---|
1525 | !! calculate fractionation (based on Diat-HadOCC; in turn based on Parekh et al., 2004) |
---|
1526 | xb_coef_tmp = xk_FeL * (xLgT - xFeT) - 1.0 |
---|
1527 | xb2M4ac = max(((xb_coef_tmp * xb_coef_tmp) + (4.0 * xk_FeL * xLgT)), 0.0) |
---|
1528 | !! |
---|
1529 | !! "free" ligand concentration |
---|
1530 | xLgF = 0.5 * (xb_coef_tmp + (xb2M4ac**0.5)) / xk_FeL |
---|
1531 | !! |
---|
1532 | !! ligand-bound iron concentration |
---|
1533 | xFeL = xLgT - xLgF |
---|
1534 | !! |
---|
1535 | !! "free" iron concentration (and convert to mmol Fe / m3) |
---|
1536 | xFeF = (xFeT - xFeL) * 1.e-3 |
---|
1537 | xFree = xFeF / (zfer + tiny(zfer)) |
---|
1538 | !! |
---|
1539 | !! scavenging of iron (multiple schemes); I'm only really happy with the |
---|
1540 | !! first one at the moment - the others involve assumptions (sometimes |
---|
1541 | !! guessed at by me) that are potentially questionable |
---|
1542 | !! |
---|
1543 | if (jiron.eq.1) then |
---|
1544 | !!---------------------------------------------------------------------- |
---|
1545 | !! Scheme 1: Dutkiewicz et al. (2005) |
---|
1546 | !! This scheme includes a single scavenging term based solely on a |
---|
1547 | !! fixed rate and the availablility of "free" iron |
---|
1548 | !!---------------------------------------------------------------------- |
---|
1549 | !! |
---|
1550 | ffescav = xk_sc_Fe * xFeF ! = mmol/m3/d |
---|
1551 | !! |
---|
1552 | !!---------------------------------------------------------------------- |
---|
1553 | !! |
---|
1554 | !! Mick's code contains a further (optional) implicit "scavenging" of |
---|
1555 | !! iron that sets an upper bound on "free" iron concentration, and |
---|
1556 | !! essentially caps the concentration of total iron as xFeL + "free" |
---|
1557 | !! iron; since the former is constrained by a fixed total ligand |
---|
1558 | !! concentration (= 1.0 umol/m3), and the latter isn't allowed above |
---|
1559 | !! this upper bound, total iron is constrained to a maximum of ... |
---|
1560 | !! |
---|
1561 | !! xFeL + min(xFeF, 0.3 umol/m3) = 1.0 + 0.3 = 1.3 umol / m3 |
---|
1562 | !! |
---|
1563 | !! In Mick's code, the actual value of total iron is reset to this |
---|
1564 | !! sum (i.e. TFe = FeL + Fe'; but Fe' <= 0.3 umol/m3); this isn't |
---|
1565 | !! our favoured approach to tracer updating here (not least because |
---|
1566 | !! of the leapfrog), so here the amount scavenged is augmented by an |
---|
1567 | !! additional amount that serves to drag total iron back towards that |
---|
1568 | !! expected from this limitation on iron concentration ... |
---|
1569 | !! |
---|
1570 | xmaxFeF = min((xFeF * 1.e3), 0.3) ! = umol/m3 |
---|
1571 | !! |
---|
1572 | !! Here, the difference between current total Fe and (FeL + Fe') is |
---|
1573 | !! calculated and added to the scavenging flux already calculated |
---|
1574 | !! above ... |
---|
1575 | !! |
---|
1576 | fdeltaFe = (xFeT - (xFeL + xmaxFeF)) * 1.e-3 ! = mmol/m3 |
---|
1577 | !! |
---|
1578 | !! This assumes that the "excess" iron is dissipated with a time- |
---|
1579 | !! scale of 1 day; seems reasonable to me ... (famous last words) |
---|
1580 | !! |
---|
1581 | ffescav = ffescav + fdeltaFe ! = mmol/m3/d |
---|
1582 | !! |
---|
1583 | # if defined key_deep_fe_fix |
---|
1584 | !! AXY (17/01/13) |
---|
1585 | !! stop scavenging for iron concentrations below 0.5 umol / m3 |
---|
1586 | !! at depths greater than 1000 m; this aims to end MEDUSA's |
---|
1587 | !! continual loss of iron at depth without impacting things |
---|
1588 | !! at the surface too much; the justification for this is that |
---|
1589 | !! it appears to be what Mick Follows et al. do in their work |
---|
1590 | !! (as evidenced by the iron initial condition they supplied |
---|
1591 | !! me with); to be honest, it looks like Follow et al. do this |
---|
1592 | !! at shallower depths than 1000 m, but I'll stick with this |
---|
1593 | !! for now; I suspect that this seemingly arbitrary approach |
---|
1594 | !! effectively "parameterises" the particle-based scavenging |
---|
1595 | !! rates that other models use (i.e. at depth there are no |
---|
1596 | !! sinking particles, so scavenging stops); it might be fun |
---|
1597 | !! justifying this in a paper though! |
---|
1598 | !! |
---|
1599 | if ((fdep.gt.1000.) .and. (xFeT.lt.0.5)) then |
---|
1600 | ffescav = 0. |
---|
1601 | endif |
---|
1602 | # endif |
---|
1603 | !! |
---|
1604 | elseif (jiron.eq.2) then |
---|
1605 | !!---------------------------------------------------------------------- |
---|
1606 | !! Scheme 2: Moore et al. (2004) |
---|
1607 | !! This scheme includes a single scavenging term that accounts for |
---|
1608 | !! both suspended and sinking particles in the water column; this |
---|
1609 | !! term scavenges total iron rather than "free" iron |
---|
1610 | !!---------------------------------------------------------------------- |
---|
1611 | !! |
---|
1612 | !! total iron concentration (mmol Fe / m3 -> umol Fe / m3) |
---|
1613 | xFeT = zfer * 1.e3 |
---|
1614 | !! |
---|
1615 | !! this has a base scavenging rate (12% / y) which is modified by local |
---|
1616 | !! particle concentration and sinking flux (and dust - but I'm ignoring |
---|
1617 | !! that here for now) and which is accelerated when Fe concentration gets |
---|
1618 | !! 0.6 nM (= 0.6 umol/m3 = 0.0006 mmol/m3), and decreased as concentrations |
---|
1619 | !! below 0.4 nM (= 0.4 umol/m3 = 0.0004 mmol/m3) |
---|
1620 | !! |
---|
1621 | !! base scavenging rate (0.12 / y) |
---|
1622 | fbase_scav = 0.12 / 365.25 |
---|
1623 | !! |
---|
1624 | !! calculate sinking particle part of scaling factor |
---|
1625 | !! this takes local fast sinking carbon (mmol C / m2 / d) and |
---|
1626 | !! gets it into nmol C / cm3 / s ("rdt" below is the number of seconds in |
---|
1627 | !! a model timestep) |
---|
1628 | !! |
---|
1629 | !! fscal_sink = ffastc(ji,jj) * 1.e2 / (86400.) |
---|
1630 | !! |
---|
1631 | !! ... actually, re-reading Moore et al.'s equations, it looks like he uses |
---|
1632 | !! his sinking flux directly, without scaling it by time-step or anything, |
---|
1633 | !! so I'll copy this here ... |
---|
1634 | !! |
---|
1635 | fscal_sink = ffastc(ji,jj) * 1.e2 |
---|
1636 | !! |
---|
1637 | !! calculate particle part of scaling factor |
---|
1638 | !! this totals up the carbon in suspended particles (Pn, Pd, Zmi, Zme, D), |
---|
1639 | !! which comes out in mmol C / m3 (= nmol C / cm3), and then multiplies it |
---|
1640 | !! by a magic factor, 0.002, to get it into nmol C / cm2 / s |
---|
1641 | !! |
---|
1642 | fscal_part = ((xthetapn * zphn) + (xthetapd * zphd) + (xthetazmi * zzmi) + & |
---|
1643 | (xthetazme * zzme) + (xthetad * zdet)) * 0.002 |
---|
1644 | !! |
---|
1645 | !! calculate scaling factor for base scavenging rate |
---|
1646 | !! this uses the (now correctly scaled) sinking flux and standing |
---|
1647 | !! particle concentration, divides through by some sort of reference |
---|
1648 | !! value (= 0.0066 nmol C / cm2 / s) and then uses this, or not if its |
---|
1649 | !! too high, to rescale the base scavenging rate |
---|
1650 | !! |
---|
1651 | fscal_scav = fbase_scav * min(((fscal_sink + fscal_part) / 0.0066), 4.0) |
---|
1652 | !! |
---|
1653 | !! the resulting scavenging rate is then scaled further according to the |
---|
1654 | !! local iron concentration (i.e. diminished in low iron regions; enhanced |
---|
1655 | !! in high iron regions; less alone in intermediate iron regions) |
---|
1656 | !! |
---|
1657 | if (xFeT.lt.0.4) then |
---|
1658 | !! |
---|
1659 | !! low iron region |
---|
1660 | !! |
---|
1661 | fscal_scav = fscal_scav * (xFeT / 0.4) |
---|
1662 | !! |
---|
1663 | elseif (xFeT.gt.0.6) then |
---|
1664 | !! |
---|
1665 | !! high iron region |
---|
1666 | !! |
---|
1667 | fscal_scav = fscal_scav + ((xFeT / 0.6) * (6.0 / 1.4)) |
---|
1668 | !! |
---|
1669 | else |
---|
1670 | !! |
---|
1671 | !! intermediate iron region: do nothing |
---|
1672 | !! |
---|
1673 | endif |
---|
1674 | !! |
---|
1675 | !! apply the calculated scavenging rate ... |
---|
1676 | !! |
---|
1677 | ffescav = fscal_scav * zfer |
---|
1678 | !! |
---|
1679 | elseif (jiron.eq.3) then |
---|
1680 | !!---------------------------------------------------------------------- |
---|
1681 | !! Scheme 3: Moore et al. (2008) |
---|
1682 | !! This scheme includes a single scavenging term that accounts for |
---|
1683 | !! sinking particles in the water column, and includes organic C, |
---|
1684 | !! biogenic opal, calcium carbonate and dust in this (though the |
---|
1685 | !! latter is ignored here until I work out what units the incoming |
---|
1686 | !! "dust" flux is in); this term scavenges total iron rather than |
---|
1687 | !! "free" iron |
---|
1688 | !!---------------------------------------------------------------------- |
---|
1689 | !! |
---|
1690 | !! total iron concentration (mmol Fe / m3 -> umol Fe / m3) |
---|
1691 | xFeT = zfer * 1.e3 |
---|
1692 | !! |
---|
1693 | !! this has a base scavenging rate which is modified by local |
---|
1694 | !! particle sinking flux (including dust - but I'm ignoring that |
---|
1695 | !! here for now) and which is accelerated when Fe concentration |
---|
1696 | !! is > 0.6 nM (= 0.6 umol/m3 = 0.0006 mmol/m3), and decreased as |
---|
1697 | !! concentrations < 0.5 nM (= 0.5 umol/m3 = 0.0005 mmol/m3) |
---|
1698 | !! |
---|
1699 | !! base scavenging rate (Fe_b in paper; units may be wrong there) |
---|
1700 | fbase_scav = 0.00384 ! (ng)^-1 cm |
---|
1701 | !! |
---|
1702 | !! calculate sinking particle part of scaling factor; this converts |
---|
1703 | !! mmol / m2 / d fluxes of organic carbon, silicon and calcium |
---|
1704 | !! carbonate into ng / cm2 / s fluxes; it is assumed here that the |
---|
1705 | !! mass conversions simply consider the mass of the main element |
---|
1706 | !! (C, Si and Ca) and *not* the mass of the molecules that they are |
---|
1707 | !! part of; Moore et al. (2008) is unclear on the conversion that |
---|
1708 | !! should be used |
---|
1709 | !! |
---|
1710 | !! milli -> nano; mol -> gram; /m2 -> /cm2; /d -> /s |
---|
1711 | fscal_csink = (ffastc(ji,jj) * 1.e6 * xmassc * 1.e-4 / 86400.) ! ng C / cm2 / s |
---|
1712 | fscal_sisink = (ffastsi(ji,jj) * 1.e6 * xmasssi * 1.e-4 / 86400.) ! ng Si / cm2 / s |
---|
1713 | fscal_casink = (ffastca(ji,jj) * 1.e6 * xmassca * 1.e-4 / 86400.) ! ng Ca / cm2 / s |
---|
1714 | !! |
---|
1715 | !! sum up these sinking fluxes and convert to ng / cm by dividing |
---|
1716 | !! through by a sinking rate of 100 m / d = 1.157 cm / s |
---|
1717 | fscal_sink = ((fscal_csink * 6.) + fscal_sisink + fscal_casink) / & |
---|
1718 | (100. * 1.e3 / 86400) ! ng / cm |
---|
1719 | !! |
---|
1720 | !! now calculate the scavenging rate based upon the base rate and |
---|
1721 | !! this particle flux scaling; according to the published units, |
---|
1722 | !! the result actually has *no* units, but as it must be expressed |
---|
1723 | !! per unit time for it to make any sense, I'm assuming a missing |
---|
1724 | !! "per second" |
---|
1725 | fscal_scav = fbase_scav * fscal_sink ! / s |
---|
1726 | !! |
---|
1727 | !! the resulting scavenging rate is then scaled further according to the |
---|
1728 | !! local iron concentration (i.e. diminished in low iron regions; enhanced |
---|
1729 | !! in high iron regions; less alone in intermediate iron regions) |
---|
1730 | !! |
---|
1731 | if (xFeT.lt.0.5) then |
---|
1732 | !! |
---|
1733 | !! low iron region (0.5 instead of the 0.4 in Moore et al., 2004) |
---|
1734 | !! |
---|
1735 | fscal_scav = fscal_scav * (xFeT / 0.5) |
---|
1736 | !! |
---|
1737 | elseif (xFeT.gt.0.6) then |
---|
1738 | !! |
---|
1739 | !! high iron region (functional form different in Moore et al., 2004) |
---|
1740 | !! |
---|
1741 | fscal_scav = fscal_scav + ((xFeT - 0.6) * 0.00904) |
---|
1742 | !! |
---|
1743 | else |
---|
1744 | !! |
---|
1745 | !! intermediate iron region: do nothing |
---|
1746 | !! |
---|
1747 | endif |
---|
1748 | !! |
---|
1749 | !! apply the calculated scavenging rate ... |
---|
1750 | !! |
---|
1751 | ffescav = fscal_scav * zfer |
---|
1752 | !! |
---|
1753 | elseif (jiron.eq.4) then |
---|
1754 | !!---------------------------------------------------------------------- |
---|
1755 | !! Scheme 4: Galbraith et al. (2010) |
---|
1756 | !! This scheme includes two scavenging terms, one for organic, |
---|
1757 | !! particle-based scavenging, and another for inorganic scavenging; |
---|
1758 | !! both terms scavenge "free" iron only |
---|
1759 | !!---------------------------------------------------------------------- |
---|
1760 | !! |
---|
1761 | !! Galbraith et al. (2010) present a more straightforward outline of |
---|
1762 | !! the scheme in Parekh et al. (2005) ... |
---|
1763 | !! |
---|
1764 | !! sinking particulate carbon available for scavenging |
---|
1765 | !! this assumes a sinking rate of 100 m / d (Moore & Braucher, 2008), |
---|
1766 | xCscav1 = (ffastc(ji,jj) * xmassc) / 100. ! = mg C / m3 |
---|
1767 | !! |
---|
1768 | !! scale by Honeyman et al. (1981) exponent coefficient |
---|
1769 | !! multiply by 1.e-3 to express C flux in g C rather than mg C |
---|
1770 | xCscav2 = (xCscav1 * 1.e-3)**0.58 |
---|
1771 | !! |
---|
1772 | !! multiply by Galbraith et al. (2010) scavenging rate |
---|
1773 | xk_org = 0.5 ! ((g C m/3)^-1) / d |
---|
1774 | xORGscav = xk_org * xCscav2 * xFeF |
---|
1775 | !! |
---|
1776 | !! Galbraith et al. (2010) also include an inorganic bit ... |
---|
1777 | !! |
---|
1778 | !! this occurs at a fixed rate, again based on the availability of |
---|
1779 | !! "free" iron |
---|
1780 | !! |
---|
1781 | !! k_inorg = 1000 d**-1 nmol Fe**-0.5 kg**-0.5 |
---|
1782 | !! |
---|
1783 | !! to implement this here, scale xFeF by 1026 to put in units of |
---|
1784 | !! umol/m3 which approximately equal nmol/kg |
---|
1785 | !! |
---|
1786 | xk_inorg = 1000. ! ((nmol Fe / kg)^1.5) |
---|
1787 | xINORGscav = (xk_inorg * (xFeF * 1026.)**1.5) * 1.e-3 |
---|
1788 | !! |
---|
1789 | !! sum these two terms together |
---|
1790 | ffescav = xORGscav + xINORGscav |
---|
1791 | else |
---|
1792 | !!---------------------------------------------------------------------- |
---|
1793 | !! No Scheme: you coward! |
---|
1794 | !! This scheme puts its head in the sand and eskews any decision about |
---|
1795 | !! how iron is removed from the ocean; prepare to get deluged in iron |
---|
1796 | !! you fool! |
---|
1797 | !!---------------------------------------------------------------------- |
---|
1798 | ffescav = 0. |
---|
1799 | endif |
---|
1800 | |
---|
1801 | !!---------------------------------------------------------------------- |
---|
1802 | !! Other iron cycle processes |
---|
1803 | !!---------------------------------------------------------------------- |
---|
1804 | !! |
---|
1805 | !! aeolian iron deposition |
---|
1806 | if (jk.eq.1) then |
---|
1807 | !! dust is in g Fe / m2 / month |
---|
1808 | !! ffetop is in mmol / m3 / day |
---|
1809 | ffetop = (((dust(ji,jj) * 1.e3 * xfe_sol) / xfe_mass) / fthk) / 30. |
---|
1810 | else |
---|
1811 | ffetop = 0.0 |
---|
1812 | endif |
---|
1813 | !! |
---|
1814 | !! seafloor iron addition |
---|
1815 | !! AXY (10/07/12): amended to only apply sedimentary flux up to ~500 m down |
---|
1816 | !! if (jk.eq.(mbathy(ji,jj)-1).AND.jk.lt.i1100) then |
---|
1817 | if (jk.eq.(mbathy(ji,jj)-1).AND.jk.le.i0500) then |
---|
1818 | !! Moore et al. (2004) cite a coastal California value of 5 umol/m2/d, but adopt a |
---|
1819 | !! global value of 2 umol/m2/d for all areas < 1100 m; here we use this latter value |
---|
1820 | !! but apply it everywhere |
---|
1821 | !! AXY (21/07/09): actually, let's just apply it below 1100 m (levels 1-37) |
---|
1822 | ffebot = (xfe_sed / fthk) |
---|
1823 | else |
---|
1824 | ffebot = 0.0 |
---|
1825 | endif |
---|
1826 | |
---|
1827 | !! AXY (16/12/09): remove iron addition/removal processes |
---|
1828 | !! For the purposes of the quarter degree run, the iron cycle is being pegged to the |
---|
1829 | !! initial condition supplied by Mick Follows via restoration with a 30 day period; |
---|
1830 | !! iron addition at the seafloor is still permitted with the idea that this extra |
---|
1831 | !! iron will be removed by the restoration away from the source |
---|
1832 | !! ffescav = 0.0 |
---|
1833 | !! ffetop = 0.0 |
---|
1834 | !! ffebot = 0.0 |
---|
1835 | |
---|
1836 | # if defined key_debug_medusa |
---|
1837 | !! report miscellaneous calculations |
---|
1838 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1839 | IF (lwp) write (numout,*) '------------------------------' |
---|
1840 | IF (lwp) write (numout,*) 'xfe_sol = ', xfe_sol |
---|
1841 | IF (lwp) write (numout,*) 'xfe_mass = ', xfe_mass |
---|
1842 | IF (lwp) write (numout,*) 'ffetop(',jk,') = ', ffetop |
---|
1843 | IF (lwp) write (numout,*) 'ffebot(',jk,') = ', ffebot |
---|
1844 | IF (lwp) write (numout,*) 'xFree(',jk,') = ', xFree |
---|
1845 | IF (lwp) write (numout,*) 'ffescav(',jk,') = ', ffescav |
---|
1846 | endif |
---|
1847 | # endif |
---|
1848 | |
---|
1849 | !!---------------------------------------------------------------------- |
---|
1850 | !! Miscellaneous |
---|
1851 | !!---------------------------------------------------------------------- |
---|
1852 | !! |
---|
1853 | !! diatom frustule dissolution |
---|
1854 | fsdiss = xsdiss * zpds |
---|
1855 | |
---|
1856 | # if defined key_debug_medusa |
---|
1857 | !! report miscellaneous calculations |
---|
1858 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
1859 | IF (lwp) write (numout,*) '------------------------------' |
---|
1860 | IF (lwp) write (numout,*) 'fsdiss(',jk,') = ', fsdiss |
---|
1861 | endif |
---|
1862 | # endif |
---|
1863 | |
---|
1864 | !!---------------------------------------------------------------------- |
---|
1865 | !! Slow detritus creation |
---|
1866 | !!---------------------------------------------------------------------- |
---|
1867 | !! this variable integrates the creation of slow sinking detritus |
---|
1868 | !! to allow the split between fast and slow detritus to be |
---|
1869 | !! diagnosed |
---|
1870 | fslown = fdpn + fdzmi + ((1.0 - xfdfrac1) * fdpd) + & |
---|
1871 | ((1.0 - xfdfrac2) * fdzme) + ((1.0 - xbetan) * (finmi + finme)) |
---|
1872 | !! |
---|
1873 | !! this variable records the slow detrital sinking flux at this |
---|
1874 | !! particular depth; it is used in the output of this flux at |
---|
1875 | !! standard depths in the diagnostic outputs; needs to be |
---|
1876 | !! adjusted from per second to per day because of parameter vsed |
---|
1877 | fslownflux = zdet * vsed * 86400. |
---|
1878 | # if defined key_roam |
---|
1879 | !! |
---|
1880 | !! and the same for detrital carbon |
---|
1881 | fslowc = (xthetapn * fdpn) + (xthetazmi * fdzmi) + & |
---|
1882 | (xthetapd * (1.0 - xfdfrac1) * fdpd) + & |
---|
1883 | (xthetazme * (1.0 - xfdfrac2) * fdzme) + & |
---|
1884 | ((1.0 - xbetac) * (ficmi + ficme)) |
---|
1885 | !! |
---|
1886 | !! this variable records the slow detrital sinking flux at this |
---|
1887 | !! particular depth; it is used in the output of this flux at |
---|
1888 | !! standard depths in the diagnostic outputs; needs to be |
---|
1889 | !! adjusted from per second to per day because of parameter vsed |
---|
1890 | fslowcflux = zdtc * vsed * 86400. |
---|
1891 | # endif |
---|
1892 | |
---|
1893 | !!---------------------------------------------------------------------- |
---|
1894 | !! Nutrient regeneration |
---|
1895 | !! this variable integrates total nitrogen regeneration down the |
---|
1896 | !! watercolumn; its value is stored and output as a 2D diagnostic; |
---|
1897 | !! the corresponding dissolution flux of silicon (from sources |
---|
1898 | !! other than fast detritus) is also integrated; note that, |
---|
1899 | !! confusingly, the linear loss terms from plankton compartments |
---|
1900 | !! are labelled as fdX2 when one might have expected fdX or fdX1 |
---|
1901 | !!---------------------------------------------------------------------- |
---|
1902 | !! |
---|
1903 | !! nitrogen |
---|
1904 | fregen = (( (xphi * (fgmipn + fgmid)) + & ! messy feeding |
---|
1905 | (xphi * (fgmepn + fgmepd + fgmezmi + fgmed)) + & ! messy feeding |
---|
1906 | fmiexcr + fmeexcr + fdd + & ! excretion + D remin. |
---|
1907 | fdpn2 + fdpd2 + fdzmi2 + fdzme2) * fthk) ! linear mortality |
---|
1908 | !! |
---|
1909 | !! silicon |
---|
1910 | fregensi = (( fsdiss + ((1.0 - xfdfrac1) * fdpds) + & ! dissolution + non-lin. mortality |
---|
1911 | ((1.0 - xfdfrac3) * fgmepds) + & ! egestion by zooplankton |
---|
1912 | fdpds2) * fthk) ! linear mortality |
---|
1913 | # if defined key_roam |
---|
1914 | !! |
---|
1915 | !! carbon |
---|
1916 | fregenc = (( (xphi * ((xthetapn * fgmipn) + fgmidc)) + & ! messy feeding |
---|
1917 | (xphi * ((xthetapn * fgmepn) + (xthetapd * fgmepd) + & ! messy feeding |
---|
1918 | (xthetazmi * fgmezmi) + fgmedc)) + & ! messy feeding |
---|
1919 | fmiresp + fmeresp + fddc + & ! respiration + D remin. |
---|
1920 | (xthetapn * fdpn2) + (xthetapd * fdpd2) + & ! linear mortality |
---|
1921 | (xthetazmi * fdzmi2) + (xthetazme * fdzme2)) * fthk) ! linear mortality |
---|
1922 | # endif |
---|
1923 | |
---|
1924 | !!---------------------------------------------------------------------- |
---|
1925 | !! Fast-sinking detritus terms |
---|
1926 | !! "local" variables declared so that conservation can be checked; |
---|
1927 | !! the calculated terms are added to the fast-sinking flux later on |
---|
1928 | !! only after the flux entering this level has experienced some |
---|
1929 | !! remineralisation |
---|
1930 | !! note: these fluxes need to be scaled by the level thickness |
---|
1931 | !!---------------------------------------------------------------------- |
---|
1932 | !! |
---|
1933 | !! nitrogen: diatom and mesozooplankton mortality |
---|
1934 | ftempn = b0 * ((xfdfrac1 * fdpd) + (xfdfrac2 * fdzme)) |
---|
1935 | !! |
---|
1936 | !! silicon: diatom mortality and grazed diatoms |
---|
1937 | ftempsi = b0 * ((xfdfrac1 * fdpds) + (xfdfrac3 * fgmepds)) |
---|
1938 | !! |
---|
1939 | !! iron: diatom and mesozooplankton mortality |
---|
1940 | ftempfe = b0 * (((xfdfrac1 * fdpd) + (xfdfrac2 * fdzme)) * xrfn) |
---|
1941 | !! |
---|
1942 | !! carbon: diatom and mesozooplankton mortality |
---|
1943 | ftempc = b0 * ((xfdfrac1 * xthetapd * fdpd) + & |
---|
1944 | (xfdfrac2 * xthetazme * fdzme)) |
---|
1945 | !! |
---|
1946 | # if defined key_roam |
---|
1947 | if (jrratio.eq.0) then |
---|
1948 | !! CaCO3: latitudinally-based fraction of total primary production |
---|
1949 | !! absolute latitude of current grid cell |
---|
1950 | flat = abs(gphit(ji,jj)) |
---|
1951 | !! 0.10 at equator; 0.02 at pole |
---|
1952 | fcaco3 = xcaco3a + ((xcaco3b - xcaco3a) * ((90.0 - flat) / 90.0)) |
---|
1953 | elseif (jrratio.eq.1) then |
---|
1954 | !! CaCO3: Ridgwell et al. (2007) submodel, version 1 |
---|
1955 | !! this uses SURFACE omega calcite to regulate rain ratio |
---|
1956 | if (f_omcal(ji,jj).ge.1.0) then |
---|
1957 | fq1 = (f_omcal(ji,jj) - 1.0)**0.81 |
---|
1958 | else |
---|
1959 | fq1 = 0. |
---|
1960 | endif |
---|
1961 | fcaco3 = xridg_r0 * fq1 |
---|
1962 | elseif (jrratio.eq.2) then |
---|
1963 | !! CaCO3: Ridgwell et al. (2007) submodel, version 2 |
---|
1964 | !! this uses FULL 3D omega calcite to regulate rain ratio |
---|
1965 | if (f3_omcal(ji,jj,jk).ge.1.0) then |
---|
1966 | fq1 = (f3_omcal(ji,jj,jk) - 1.0)**0.81 |
---|
1967 | else |
---|
1968 | fq1 = 0. |
---|
1969 | endif |
---|
1970 | fcaco3 = xridg_r0 * fq1 |
---|
1971 | endif |
---|
1972 | # else |
---|
1973 | !! CaCO3: latitudinally-based fraction of total primary production |
---|
1974 | !! absolute latitude of current grid cell |
---|
1975 | flat = abs(gphit(ji,jj)) |
---|
1976 | !! 0.10 at equator; 0.02 at pole |
---|
1977 | fcaco3 = xcaco3a + ((xcaco3b - xcaco3a) * ((90.0 - flat) / 90.0)) |
---|
1978 | # endif |
---|
1979 | !! AXY (09/03/09): convert CaCO3 production from function of |
---|
1980 | !! primary production into a function of fast-sinking material; |
---|
1981 | !! technically, this is what Dunne et al. (2007) do anyway; they |
---|
1982 | !! convert total primary production estimated from surface |
---|
1983 | !! chlorophyll to an export flux for which they apply conversion |
---|
1984 | !! factors to estimate the various elemental fractions (Si, Ca) |
---|
1985 | ftempca = ftempc * fcaco3 |
---|
1986 | |
---|
1987 | # if defined key_debug_medusa |
---|
1988 | !! integrate total fast detritus production |
---|
1989 | if (idf.eq.1) then |
---|
1990 | fifd_n(ji,jj) = fifd_n(ji,jj) + (ftempn * fthk) |
---|
1991 | fifd_si(ji,jj) = fifd_si(ji,jj) + (ftempsi * fthk) |
---|
1992 | fifd_fe(ji,jj) = fifd_fe(ji,jj) + (ftempfe * fthk) |
---|
1993 | # if defined key_roam |
---|
1994 | fifd_c(ji,jj) = fifd_c(ji,jj) + (ftempc * fthk) |
---|
1995 | # endif |
---|
1996 | endif |
---|
1997 | |
---|
1998 | !! report quantities of fast-sinking detritus for each component |
---|
1999 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
2000 | IF (lwp) write (numout,*) '------------------------------' |
---|
2001 | IF (lwp) write (numout,*) 'fdpd(',jk,') = ', fdpd |
---|
2002 | IF (lwp) write (numout,*) 'fdzme(',jk,') = ', fdzme |
---|
2003 | IF (lwp) write (numout,*) 'ftempn(',jk,') = ', ftempn |
---|
2004 | IF (lwp) write (numout,*) 'ftempsi(',jk,') = ', ftempsi |
---|
2005 | IF (lwp) write (numout,*) 'ftempfe(',jk,') = ', ftempfe |
---|
2006 | IF (lwp) write (numout,*) 'ftempc(',jk,') = ', ftempc |
---|
2007 | IF (lwp) write (numout,*) 'ftempca(',jk,') = ', ftempca |
---|
2008 | IF (lwp) write (numout,*) 'flat(',jk,') = ', flat |
---|
2009 | IF (lwp) write (numout,*) 'fcaco3(',jk,') = ', fcaco3 |
---|
2010 | endif |
---|
2011 | # endif |
---|
2012 | |
---|
2013 | !!---------------------------------------------------------------------- |
---|
2014 | !! This version of MEDUSA offers a choice of three methods for |
---|
2015 | !! handling the remineralisation of fast detritus. All three |
---|
2016 | !! do so in broadly the same way: |
---|
2017 | !! |
---|
2018 | !! 1. Fast detritus is stored as a 2D array [ ffastX ] |
---|
2019 | !! 2. Fast detritus is added level-by-level [ ftempX ] |
---|
2020 | !! 3. Fast detritus is not remineralised in the top box [ freminX ] |
---|
2021 | !! 4. Remaining fast detritus is remineralised in the bottom [ fsedX ] |
---|
2022 | !! box |
---|
2023 | !! |
---|
2024 | !! The three remineralisation methods are: |
---|
2025 | !! |
---|
2026 | !! 1. Ballast model (i.e. that published in Yool et al., 2011) |
---|
2027 | !! (1b. Ballast-sans-ballast model) |
---|
2028 | !! 2. Martin et al. (1987) |
---|
2029 | !! 3. Henson et al. (2011) |
---|
2030 | !! |
---|
2031 | !! The first of these couples C, N and Fe remineralisation to |
---|
2032 | !! the remineralisation of particulate Si and CaCO3, but the |
---|
2033 | !! latter two treat remineralisation of C, N, Fe, Si and CaCO3 |
---|
2034 | !! completely separately. At present a switch within the code |
---|
2035 | !! regulates which submodel is used, but this should be moved |
---|
2036 | !! to the namelist file. |
---|
2037 | !! |
---|
2038 | !! The ballast-sans-ballast submodel is an original development |
---|
2039 | !! feature of MEDUSA in which the ballast submodel's general |
---|
2040 | !! framework and parameterisation is used, but in which there |
---|
2041 | !! is no protection of organic material afforded by ballasting |
---|
2042 | !! minerals. While similar, it is not the same as the Martin |
---|
2043 | !! et al. (1987) submodel. |
---|
2044 | !! |
---|
2045 | !! Since the three submodels behave the same in terms of |
---|
2046 | !! accumulating sinking material and remineralising it all at |
---|
2047 | !! the seafloor, these portions of the code below are common to |
---|
2048 | !! all three. |
---|
2049 | !!---------------------------------------------------------------------- |
---|
2050 | |
---|
2051 | if (jexport.eq.1) then |
---|
2052 | !!====================================================================== |
---|
2053 | !! BALLAST SUBMODEL |
---|
2054 | !!====================================================================== |
---|
2055 | !! |
---|
2056 | !!---------------------------------------------------------------------- |
---|
2057 | !! Fast-sinking detritus fluxes, pt. 1: REMINERALISATION |
---|
2058 | !! aside from explicitly modelled, slow-sinking detritus, the |
---|
2059 | !! model includes an implicit representation of detrital |
---|
2060 | !! particles that sink too quickly to be modelled with |
---|
2061 | !! explicit state variables; this sinking flux is instead |
---|
2062 | !! instantaneously remineralised down the water column using |
---|
2063 | !! the version of Armstrong et al. (2002)'s ballast model |
---|
2064 | !! used by Dunne et al. (2007); the version of this model |
---|
2065 | !! here considers silicon and calcium carbonate ballast |
---|
2066 | !! minerals; this section of the code redistributes the fast |
---|
2067 | !! sinking material generated locally down the water column; |
---|
2068 | !! this differs from Dunne et al. (2007) in that fast sinking |
---|
2069 | !! material is distributed at *every* level below that it is |
---|
2070 | !! generated, rather than at every level below some fixed |
---|
2071 | !! depth; this scheme is also different in that sinking material |
---|
2072 | !! generated in one level is aggregated with that generated by |
---|
2073 | !! shallower levels; this should make the ballast model more |
---|
2074 | !! self-consistent (famous last words) |
---|
2075 | !!---------------------------------------------------------------------- |
---|
2076 | !! |
---|
2077 | if (jk.eq.1) then |
---|
2078 | !! this is the SURFACE OCEAN BOX (no remineralisation) |
---|
2079 | !! |
---|
2080 | freminc = 0.0 |
---|
2081 | freminn = 0.0 |
---|
2082 | freminfe = 0.0 |
---|
2083 | freminsi = 0.0 |
---|
2084 | freminca = 0.0 |
---|
2085 | elseif (jk.lt.(mbathy(ji,jj))) then |
---|
2086 | !! this is an OCEAN BOX (remineralise some material) |
---|
2087 | !! |
---|
2088 | !! set up CCD depth to be used depending on user choice |
---|
2089 | if (jocalccd.eq.0) then |
---|
2090 | !! use default CCD field |
---|
2091 | fccd_dep = ocal_ccd(ji,jj) |
---|
2092 | elseif (jocalccd.eq.1) then |
---|
2093 | !! use calculated CCD field |
---|
2094 | fccd_dep = f2_ccd_cal(ji,jj) |
---|
2095 | endif |
---|
2096 | !! |
---|
2097 | !! === organic carbon === |
---|
2098 | fq0 = ffastc(ji,jj) !! how much organic C enters this box (mol) |
---|
2099 | if (iball.eq.1) then |
---|
2100 | fq1 = (fq0 * xmassc) !! how much it weighs (mass) |
---|
2101 | fq2 = (ffastca(ji,jj) * xmassca) !! how much CaCO3 enters this box (mass) |
---|
2102 | fq3 = (ffastsi(ji,jj) * xmasssi) !! how much opal enters this box (mass) |
---|
2103 | fq4 = (fq2 * xprotca) + (fq3 * xprotsi) !! total protected organic C (mass) |
---|
2104 | !! this next term is calculated for C but used for N and Fe as well |
---|
2105 | !! it needs to be protected in case ALL C is protected |
---|
2106 | if (fq4.lt.fq1) then |
---|
2107 | fprotf = (fq4 / (fq1 + tiny(fq1))) !! protected fraction of total organic C (non-dim) |
---|
2108 | else |
---|
2109 | fprotf = 1.0 !! all organic C is protected (non-dim) |
---|
2110 | endif |
---|
2111 | fq5 = (1.0 - fprotf) !! unprotected fraction of total organic C (non-dim) |
---|
2112 | fq6 = (fq0 * fq5) !! how much organic C is unprotected (mol) |
---|
2113 | fq7 = (fq6 * exp(-(fthk / xfastc))) !! how much unprotected C leaves this box (mol) |
---|
2114 | fq8 = (fq7 + (fq0 * fprotf)) !! how much total C leaves this box (mol) |
---|
2115 | freminc = (fq0 - fq8) / fthk !! C remineralisation in this box (mol) |
---|
2116 | ffastc(ji,jj) = fq8 |
---|
2117 | # if defined key_debug_medusa |
---|
2118 | !! report in/out/remin fluxes of carbon for this level |
---|
2119 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
2120 | IF (lwp) write (numout,*) '------------------------------' |
---|
2121 | IF (lwp) write (numout,*) 'totalC(',jk,') = ', fq1 |
---|
2122 | IF (lwp) write (numout,*) 'prtctC(',jk,') = ', fq4 |
---|
2123 | IF (lwp) write (numout,*) 'fprotf(',jk,') = ', fprotf |
---|
2124 | IF (lwp) write (numout,*) '------------------------------' |
---|
2125 | IF (lwp) write (numout,*) 'IN C(',jk,') = ', fq0 |
---|
2126 | IF (lwp) write (numout,*) 'LOST C(',jk,') = ', freminc * fthk |
---|
2127 | IF (lwp) write (numout,*) 'OUT C(',jk,') = ', fq8 |
---|
2128 | IF (lwp) write (numout,*) 'NEW C(',jk,') = ', ftempc * fthk |
---|
2129 | endif |
---|
2130 | # endif |
---|
2131 | else |
---|
2132 | fq1 = fq0 * exp(-(fthk / xfastc)) !! how much organic C leaves this box (mol) |
---|
2133 | freminc = (fq0 - fq1) / fthk !! C remineralisation in this box (mol) |
---|
2134 | ffastc(ji,jj) = fq1 |
---|
2135 | endif |
---|
2136 | !! |
---|
2137 | !! === organic nitrogen === |
---|
2138 | fq0 = ffastn(ji,jj) !! how much organic N enters this box (mol) |
---|
2139 | if (iball.eq.1) then |
---|
2140 | fq5 = (1.0 - fprotf) !! unprotected fraction of total organic N (non-dim) |
---|
2141 | fq6 = (fq0 * fq5) !! how much organic N is unprotected (mol) |
---|
2142 | fq7 = (fq6 * exp(-(fthk / xfastc))) !! how much unprotected N leaves this box (mol) |
---|
2143 | fq8 = (fq7 + (fq0 * fprotf)) !! how much total N leaves this box (mol) |
---|
2144 | freminn = (fq0 - fq8) / fthk !! N remineralisation in this box (mol) |
---|
2145 | ffastn(ji,jj) = fq8 |
---|
2146 | # if defined key_debug_medusa |
---|
2147 | !! report in/out/remin fluxes of carbon for this level |
---|
2148 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
2149 | IF (lwp) write (numout,*) '------------------------------' |
---|
2150 | IF (lwp) write (numout,*) 'totalN(',jk,') = ', fq1 |
---|
2151 | IF (lwp) write (numout,*) 'prtctN(',jk,') = ', fq4 |
---|
2152 | IF (lwp) write (numout,*) 'fprotf(',jk,') = ', fprotf |
---|
2153 | IF (lwp) write (numout,*) '------------------------------' |
---|
2154 | if (freminn < 0.0) then |
---|
2155 | IF (lwp) write (numout,*) '** FREMIN ERROR **' |
---|
2156 | endif |
---|
2157 | IF (lwp) write (numout,*) 'IN N(',jk,') = ', fq0 |
---|
2158 | IF (lwp) write (numout,*) 'LOST N(',jk,') = ', freminn * fthk |
---|
2159 | IF (lwp) write (numout,*) 'OUT N(',jk,') = ', fq8 |
---|
2160 | IF (lwp) write (numout,*) 'NEW N(',jk,') = ', ftempn * fthk |
---|
2161 | endif |
---|
2162 | # endif |
---|
2163 | else |
---|
2164 | fq1 = fq0 * exp(-(fthk / xfastc)) !! how much organic N leaves this box (mol) |
---|
2165 | freminn = (fq0 - fq1) / fthk !! N remineralisation in this box (mol) |
---|
2166 | ffastn(ji,jj) = fq1 |
---|
2167 | endif |
---|
2168 | !! |
---|
2169 | !! === organic iron === |
---|
2170 | fq0 = ffastfe(ji,jj) !! how much organic Fe enters this box (mol) |
---|
2171 | if (iball.eq.1) then |
---|
2172 | fq5 = (1.0 - fprotf) !! unprotected fraction of total organic Fe (non-dim) |
---|
2173 | fq6 = (fq0 * fq5) !! how much organic Fe is unprotected (mol) |
---|
2174 | fq7 = (fq6 * exp(-(fthk / xfastc))) !! how much unprotected Fe leaves this box (mol) |
---|
2175 | fq8 = (fq7 + (fq0 * fprotf)) !! how much total Fe leaves this box (mol) |
---|
2176 | freminfe = (fq0 - fq8) / fthk !! Fe remineralisation in this box (mol) |
---|
2177 | ffastfe(ji,jj) = fq8 |
---|
2178 | else |
---|
2179 | fq1 = fq0 * exp(-(fthk / xfastc)) !! how much total Fe leaves this box (mol) |
---|
2180 | freminfe = (fq0 - fq1) / fthk !! Fe remineralisation in this box (mol) |
---|
2181 | ffastfe(ji,jj) = fq1 |
---|
2182 | endif |
---|
2183 | !! |
---|
2184 | !! === biogenic silicon === |
---|
2185 | fq0 = ffastsi(ji,jj) !! how much opal centers this box (mol) |
---|
2186 | fq1 = fq0 * exp(-(fthk / xfastsi)) !! how much opal leaves this box (mol) |
---|
2187 | freminsi = (fq0 - fq1) / fthk !! Si remineralisation in this box (mol) |
---|
2188 | ffastsi(ji,jj) = fq1 |
---|
2189 | !! |
---|
2190 | !! === biogenic calcium carbonate === |
---|
2191 | fq0 = ffastca(ji,jj) !! how much CaCO3 enters this box (mol) |
---|
2192 | if (fdep.le.fccd_dep) then |
---|
2193 | !! whole grid cell above CCD |
---|
2194 | fq1 = fq0 !! above lysocline, no Ca dissolves (mol) |
---|
2195 | freminca = 0.0 !! above lysocline, no Ca dissolves (mol) |
---|
2196 | fccd(ji,jj) = real(jk) !! which is the last level above the CCD? (#) |
---|
2197 | elseif (fdep.ge.fccd_dep) then |
---|
2198 | !! whole grid cell below CCD |
---|
2199 | fq1 = fq0 * exp(-(fthk / xfastca)) !! how much CaCO3 leaves this box (mol) |
---|
2200 | freminca = (fq0 - fq1) / fthk !! Ca remineralisation in this box (mol) |
---|
2201 | else |
---|
2202 | !! partial grid cell below CCD |
---|
2203 | fq2 = fdep1 - fccd_dep !! amount of grid cell below CCD (m) |
---|
2204 | fq1 = fq0 * exp(-(fq2 / xfastca)) !! how much CaCO3 leaves this box (mol) |
---|
2205 | freminca = (fq0 - fq1) / fthk !! Ca remineralisation in this box (mol) |
---|
2206 | endif |
---|
2207 | ffastca(ji,jj) = fq1 |
---|
2208 | else |
---|
2209 | !! this is BELOW THE LAST OCEAN BOX (do nothing) |
---|
2210 | freminc = 0.0 |
---|
2211 | freminn = 0.0 |
---|
2212 | freminfe = 0.0 |
---|
2213 | freminsi = 0.0 |
---|
2214 | freminca = 0.0 |
---|
2215 | endif |
---|
2216 | |
---|
2217 | elseif (jexport.eq.2.or.jexport.eq.3) then |
---|
2218 | if (jexport.eq.2) then |
---|
2219 | !!====================================================================== |
---|
2220 | !! MARTIN ET AL. (1987) SUBMODEL |
---|
2221 | !!====================================================================== |
---|
2222 | !! |
---|
2223 | !!---------------------------------------------------------------------- |
---|
2224 | !! This submodel uses the classic Martin et al. (1987) curve |
---|
2225 | !! to determine the attenuation of fast-sinking detritus down |
---|
2226 | !! the water column. All three organic elements, C, N and Fe, |
---|
2227 | !! are handled identically, and their quantities in sinking |
---|
2228 | !! particles attenuate according to a power relationship |
---|
2229 | !! governed by parameter "b". This is assigned a canonical |
---|
2230 | !! value of -0.858. Biogenic opal and calcium carbonate are |
---|
2231 | !! attentuated using the same function as in the ballast |
---|
2232 | !! submodel |
---|
2233 | !!---------------------------------------------------------------------- |
---|
2234 | !! |
---|
2235 | fb_val = -0.858 |
---|
2236 | elseif (jexport.eq.3) then |
---|
2237 | !!====================================================================== |
---|
2238 | !! HENSON ET AL. (2011) SUBMODEL |
---|
2239 | !!====================================================================== |
---|
2240 | !! |
---|
2241 | !!---------------------------------------------------------------------- |
---|
2242 | !! This submodel reconfigures the Martin et al. (1987) curve by |
---|
2243 | !! allowing the "b" value to vary geographically. Its value is |
---|
2244 | !! set, following Henson et al. (2011), as a function of local |
---|
2245 | !! sea surface temperature: |
---|
2246 | !! b = -1.06 + (0.024 * SST) |
---|
2247 | !! This means that remineralisation length scales are longer in |
---|
2248 | !! warm, tropical areas and shorter in cold, polar areas. This |
---|
2249 | !! does seem back-to-front (i.e. one would expect GREATER |
---|
2250 | !! remineralisation in warmer waters), but is an outcome of |
---|
2251 | !! analysis of sediment trap data, and it may reflect details |
---|
2252 | !! of ecosystem structure that pertain to particle production |
---|
2253 | !! rather than simply Q10. |
---|
2254 | !!---------------------------------------------------------------------- |
---|
2255 | !! |
---|
2256 | fl_sst = tsn(ji,jj,1,jp_tem) |
---|
2257 | fb_val = -1.06 + (0.024 * fl_sst) |
---|
2258 | endif |
---|
2259 | !! |
---|
2260 | if (jk.eq.1) then |
---|
2261 | !! this is the SURFACE OCEAN BOX (no remineralisation) |
---|
2262 | !! |
---|
2263 | freminc = 0.0 |
---|
2264 | freminn = 0.0 |
---|
2265 | freminfe = 0.0 |
---|
2266 | freminsi = 0.0 |
---|
2267 | freminca = 0.0 |
---|
2268 | elseif (jk.lt.(mbathy(ji,jj))) then |
---|
2269 | !! this is an OCEAN BOX (remineralise some material) |
---|
2270 | !! |
---|
2271 | !! === organic carbon === |
---|
2272 | fq0 = ffastc(ji,jj) !! how much organic C enters this box (mol) |
---|
2273 | fq1 = fq0 * ((fdep1/fdep)**fb_val) !! how much organic C leaves this box (mol) |
---|
2274 | freminc = (fq0 - fq1) / fthk !! C remineralisation in this box (mol) |
---|
2275 | ffastc(ji,jj) = fq1 |
---|
2276 | !! |
---|
2277 | !! === organic nitrogen === |
---|
2278 | fq0 = ffastn(ji,jj) !! how much organic N enters this box (mol) |
---|
2279 | fq1 = fq0 * ((fdep1/fdep)**fb_val) !! how much organic N leaves this box (mol) |
---|
2280 | freminn = (fq0 - fq1) / fthk !! N remineralisation in this box (mol) |
---|
2281 | ffastn(ji,jj) = fq1 |
---|
2282 | !! |
---|
2283 | !! === organic iron === |
---|
2284 | fq0 = ffastfe(ji,jj) !! how much organic Fe enters this box (mol) |
---|
2285 | fq1 = fq0 * ((fdep1/fdep)**fb_val) !! how much organic Fe leaves this box (mol) |
---|
2286 | freminfe = (fq0 - fq1) / fthk !! Fe remineralisation in this box (mol) |
---|
2287 | ffastfe(ji,jj) = fq1 |
---|
2288 | !! |
---|
2289 | !! === biogenic silicon === |
---|
2290 | fq0 = ffastsi(ji,jj) !! how much opal centers this box (mol) |
---|
2291 | fq1 = fq0 * exp(-(fthk / xfastsi)) !! how much opal leaves this box (mol) |
---|
2292 | freminsi = (fq0 - fq1) / fthk !! Si remineralisation in this box (mol) |
---|
2293 | ffastsi(ji,jj) = fq1 |
---|
2294 | !! |
---|
2295 | !! === biogenic calcium carbonate === |
---|
2296 | fq0 = ffastca(ji,jj) !! how much CaCO3 enters this box (mol) |
---|
2297 | if (fdep.le.ocal_ccd(ji,jj)) then |
---|
2298 | !! whole grid cell above CCD |
---|
2299 | fq1 = fq0 !! above lysocline, no Ca dissolves (mol) |
---|
2300 | freminca = 0.0 !! above lysocline, no Ca dissolves (mol) |
---|
2301 | fccd(ji,jj) = real(jk) !! which is the last level above the CCD? (#) |
---|
2302 | elseif (fdep.ge.ocal_ccd(ji,jj)) then |
---|
2303 | !! whole grid cell below CCD |
---|
2304 | fq1 = fq0 * exp(-(fthk / xfastca)) !! how much CaCO3 leaves this box (mol) |
---|
2305 | freminca = (fq0 - fq1) / fthk !! Ca remineralisation in this box (mol) |
---|
2306 | else |
---|
2307 | !! partial grid cell below CCD |
---|
2308 | fq2 = fdep1 - ocal_ccd(ji,jj) !! amount of grid cell below CCD (m) |
---|
2309 | fq1 = fq0 * exp(-(fq2 / xfastca)) !! how much CaCO3 leaves this box (mol) |
---|
2310 | freminca = (fq0 - fq1) / fthk !! Ca remineralisation in this box (mol) |
---|
2311 | endif |
---|
2312 | ffastca(ji,jj) = fq1 |
---|
2313 | else |
---|
2314 | !! this is BELOW THE LAST OCEAN BOX (do nothing) |
---|
2315 | freminc = 0.0 |
---|
2316 | freminn = 0.0 |
---|
2317 | freminfe = 0.0 |
---|
2318 | freminsi = 0.0 |
---|
2319 | freminca = 0.0 |
---|
2320 | endif |
---|
2321 | |
---|
2322 | endif |
---|
2323 | |
---|
2324 | !!---------------------------------------------------------------------- |
---|
2325 | !! Fast-sinking detritus fluxes, pt. 2: UPDATE FAST FLUXES |
---|
2326 | !! here locally calculated additions to the fast-sinking flux are added |
---|
2327 | !! to the total fast-sinking flux; this is done here such that material |
---|
2328 | !! produced in a particular layer is only remineralised below this |
---|
2329 | !! layer |
---|
2330 | !!---------------------------------------------------------------------- |
---|
2331 | !! |
---|
2332 | !! add sinking material generated in this layer to running totals |
---|
2333 | !! |
---|
2334 | !! === organic carbon === (diatom and mesozooplankton mortality) |
---|
2335 | ffastc(ji,jj) = ffastc(ji,jj) + (ftempc * fthk) |
---|
2336 | !! |
---|
2337 | !! === organic nitrogen === (diatom and mesozooplankton mortality) |
---|
2338 | ffastn(ji,jj) = ffastn(ji,jj) + (ftempn * fthk) |
---|
2339 | !! |
---|
2340 | !! === organic iron === (diatom and mesozooplankton mortality) |
---|
2341 | ffastfe(ji,jj) = ffastfe(ji,jj) + (ftempfe * fthk) |
---|
2342 | !! |
---|
2343 | !! === biogenic silicon === (diatom mortality and grazed diatoms) |
---|
2344 | ffastsi(ji,jj) = ffastsi(ji,jj) + (ftempsi * fthk) |
---|
2345 | !! |
---|
2346 | !! === biogenic calcium carbonate === (latitudinally-based fraction of total primary production) |
---|
2347 | ffastca(ji,jj) = ffastca(ji,jj) + (ftempca * fthk) |
---|
2348 | |
---|
2349 | !!---------------------------------------------------------------------- |
---|
2350 | !! Fast-sinking detritus fluxes, pt. 3: SEAFLOOR |
---|
2351 | !! remineralise all remaining fast-sinking detritus to dissolved |
---|
2352 | !! nutrients; the sedimentation fluxes calculated here allow the |
---|
2353 | !! separation of what's remineralised sinking through the final |
---|
2354 | !! ocean box from that which is added to the final box by the |
---|
2355 | !! remineralisation of material that reaches the seafloor (i.e. |
---|
2356 | !! the model assumes that *all* material that hits the seafloor |
---|
2357 | !! is remineralised and that none is permanently buried; hey, |
---|
2358 | !! this is a giant GCM model that can't be run for long enough |
---|
2359 | !! to deal with burial fluxes!) |
---|
2360 | !! |
---|
2361 | !! in a change to this process, in part so that MEDUSA behaves |
---|
2362 | !! a little more like ERSEM et al., fast-sinking detritus (N, Fe |
---|
2363 | !! and C) is converted to slow sinking detritus at the seafloor |
---|
2364 | !! instead of being remineralised; the rationale is that in |
---|
2365 | !! shallower shelf regions (... that are not fully mixed!) this |
---|
2366 | !! allows the detrital material to return slowly to dissolved |
---|
2367 | !! nutrient rather than instantaneously as now; the alternative |
---|
2368 | !! would be to explicitly handle seafloor organic material - a |
---|
2369 | !! headache I don't wish to experience at this point; note that |
---|
2370 | !! fast-sinking Si and Ca detritus is just remineralised as |
---|
2371 | !! per usual |
---|
2372 | !! |
---|
2373 | !! AXY (13/01/12) |
---|
2374 | !! in a further change to this process, again so that MEDUSA is |
---|
2375 | !! a little more like ERSEM et al., material that reaches the |
---|
2376 | !! seafloor can now be added to sediment pools and stored for |
---|
2377 | !! slow release; there are new 2D arrays for organic nitrogen, |
---|
2378 | !! iron and carbon and inorganic silicon and carbon that allow |
---|
2379 | !! fast and slow detritus that reaches the seafloor to be held |
---|
2380 | !! and released back to the water column more slowly; these arrays |
---|
2381 | !! are transferred via the tracer restart files between repeat |
---|
2382 | !! submissions of the model |
---|
2383 | !!---------------------------------------------------------------------- |
---|
2384 | !! |
---|
2385 | ffast2slowc = 0.0 |
---|
2386 | ffast2slown = 0.0 |
---|
2387 | ffast2slowfe = 0.0 |
---|
2388 | !! |
---|
2389 | if (jk.eq.(mbathy(ji,jj)-1)) then |
---|
2390 | !! this is the BOTTOM OCEAN BOX (remineralise everything) |
---|
2391 | !! |
---|
2392 | !! AXY (17/01/12): tweaked to include benthos pools |
---|
2393 | !! |
---|
2394 | !! === organic carbon === |
---|
2395 | if (jfdfate.eq.0 .and. jorgben.eq.0) then |
---|
2396 | freminc = freminc + (ffastc(ji,jj) / fthk) !! C remineralisation in this box (mol/m3) |
---|
2397 | elseif (jfdfate.eq.1 .and. jorgben.eq.0) then |
---|
2398 | ffast2slowc = ffastc(ji,jj) / fthk !! fast C -> slow C (mol/m3) |
---|
2399 | fslowc = fslowc + ffast2slowc |
---|
2400 | elseif (jfdfate.eq.0 .and. jorgben.eq.1) then |
---|
2401 | f_fbenin_c(ji,jj) = ffastc(ji,jj) !! fast C -> benthic C (mol/m2) |
---|
2402 | endif |
---|
2403 | fsedc = ffastc(ji,jj) !! record seafloor C (mol/m2) |
---|
2404 | ffastc(ji,jj) = 0.0 |
---|
2405 | !! |
---|
2406 | !! === organic nitrogen === |
---|
2407 | if (jfdfate.eq.0 .and. jorgben.eq.0) then |
---|
2408 | freminn = freminn + (ffastn(ji,jj) / fthk) !! N remineralisation in this box (mol/m3) |
---|
2409 | elseif (jfdfate.eq.1 .and. jorgben.eq.0) then |
---|
2410 | ffast2slown = ffastn(ji,jj) / fthk !! fast N -> slow N (mol/m3) |
---|
2411 | fslown = fslown + ffast2slown |
---|
2412 | elseif (jfdfate.eq.0 .and. jorgben.eq.1) then |
---|
2413 | f_fbenin_n(ji,jj) = ffastn(ji,jj) !! fast N -> benthic N (mol/m2) |
---|
2414 | endif |
---|
2415 | fsedn = ffastn(ji,jj) !! record seafloor N (mol/m2) |
---|
2416 | ffastn(ji,jj) = 0.0 |
---|
2417 | !! |
---|
2418 | !! === organic iron === |
---|
2419 | if (jfdfate.eq.0 .and. jorgben.eq.0) then |
---|
2420 | freminfe = freminfe + (ffastfe(ji,jj) / fthk) !! Fe remineralisation in this box (mol/m3) |
---|
2421 | elseif (jfdfate.eq.1 .and. jorgben.eq.0) then |
---|
2422 | ffast2slowfe = ffastn(ji,jj) / fthk !! fast Fe -> slow Fe (mol/m3) |
---|
2423 | elseif (jfdfate.eq.0 .and. jorgben.eq.1) then |
---|
2424 | f_fbenin_fe(ji,jj) = ffastfe(ji,jj) !! fast Fe -> benthic Fe (mol/m2) |
---|
2425 | endif |
---|
2426 | fsedfe = ffastfe(ji,jj) !! record seafloor Fe (mol/m2) |
---|
2427 | ffastfe(ji,jj) = 0.0 |
---|
2428 | !! |
---|
2429 | !! === biogenic silicon === |
---|
2430 | if (jinorgben.eq.0) then |
---|
2431 | freminsi = freminsi + (ffastsi(ji,jj) / fthk) !! Si remineralisation in this box (mol/m3) |
---|
2432 | elseif (jinorgben.eq.1) then |
---|
2433 | f_fbenin_si(ji,jj) = ffastsi(ji,jj) !! fast Si -> benthic Si (mol/m2) |
---|
2434 | endif |
---|
2435 | fsedsi = ffastsi(ji,jj) !! record seafloor Si (mol/m2) |
---|
2436 | ffastsi(ji,jj) = 0.0 |
---|
2437 | !! |
---|
2438 | !! === biogenic calcium carbonate === |
---|
2439 | if (jinorgben.eq.0) then |
---|
2440 | freminca = freminca + (ffastca(ji,jj) / fthk) !! Ca remineralisation in this box (mol/m3) |
---|
2441 | elseif (jinorgben.eq.1) then |
---|
2442 | f_fbenin_ca(ji,jj) = ffastca(ji,jj) !! fast Ca -> benthic Ca (mol/m2) |
---|
2443 | endif |
---|
2444 | fsedca = ffastca(ji,jj) !! record seafloor Ca (mol/m2) |
---|
2445 | ffastca(ji,jj) = 0.0 |
---|
2446 | endif |
---|
2447 | |
---|
2448 | # if defined key_debug_medusa |
---|
2449 | if (idf.eq.1) then |
---|
2450 | !!---------------------------------------------------------------------- |
---|
2451 | !! Integrate total fast detritus remineralisation |
---|
2452 | !!---------------------------------------------------------------------- |
---|
2453 | !! |
---|
2454 | fofd_n(ji,jj) = fofd_n(ji,jj) + (freminn * fthk) |
---|
2455 | fofd_si(ji,jj) = fofd_si(ji,jj) + (freminsi * fthk) |
---|
2456 | fofd_fe(ji,jj) = fofd_fe(ji,jj) + (freminfe * fthk) |
---|
2457 | # if defined key_roam |
---|
2458 | fofd_c(ji,jj) = fofd_c(ji,jj) + (freminc * fthk) |
---|
2459 | # endif |
---|
2460 | endif |
---|
2461 | # endif |
---|
2462 | |
---|
2463 | !!---------------------------------------------------------------------- |
---|
2464 | !! Sort out remineralisation tally of fast-sinking detritus |
---|
2465 | !!---------------------------------------------------------------------- |
---|
2466 | !! |
---|
2467 | !! update fast-sinking regeneration arrays |
---|
2468 | fregenfast(ji,jj) = fregenfast(ji,jj) + (freminn * fthk) |
---|
2469 | fregenfastsi(ji,jj) = fregenfastsi(ji,jj) + (freminsi * fthk) |
---|
2470 | # if defined key_roam |
---|
2471 | fregenfastc(ji,jj) = fregenfastc(ji,jj) + (freminc * fthk) |
---|
2472 | # endif |
---|
2473 | |
---|
2474 | !!---------------------------------------------------------------------- |
---|
2475 | !! Benthic remineralisation fluxes |
---|
2476 | !!---------------------------------------------------------------------- |
---|
2477 | !! |
---|
2478 | if (jk.eq.(mbathy(ji,jj)-1)) then |
---|
2479 | !! |
---|
2480 | !! organic components |
---|
2481 | if (jorgben.eq.1) then |
---|
2482 | f_benout_n(ji,jj) = xsedn * zn_sed_n(ji,jj) |
---|
2483 | f_benout_fe(ji,jj) = xsedfe * zn_sed_fe(ji,jj) |
---|
2484 | f_benout_c(ji,jj) = xsedc * zn_sed_c(ji,jj) |
---|
2485 | endif |
---|
2486 | !! |
---|
2487 | !! inorganic components |
---|
2488 | if (jinorgben.eq.1) then |
---|
2489 | f_benout_si(ji,jj) = xsedsi * zn_sed_si(ji,jj) |
---|
2490 | f_benout_ca(ji,jj) = xsedca * zn_sed_ca(ji,jj) |
---|
2491 | !! |
---|
2492 | !! account for CaCO3 that dissolves when it shouldn't |
---|
2493 | if ( fdep .le. fccd_dep ) then |
---|
2494 | f_benout_lyso_ca(ji,jj) = xsedca * zn_sed_ca(ji,jj) |
---|
2495 | endif |
---|
2496 | endif |
---|
2497 | endif |
---|
2498 | CALL flush(numout) |
---|
2499 | |
---|
2500 | !!====================================================================== |
---|
2501 | !! LOCAL GRID CELL TRENDS |
---|
2502 | !!====================================================================== |
---|
2503 | !! |
---|
2504 | !!---------------------------------------------------------------------- |
---|
2505 | !! Determination of trends |
---|
2506 | !!---------------------------------------------------------------------- |
---|
2507 | !! |
---|
2508 | !!---------------------------------------------------------------------- |
---|
2509 | !! chlorophyll |
---|
2510 | btra(jpchn) = b0 * ( & |
---|
2511 | + ((frn * fprn * zphn) - fgmipn - fgmepn - fdpn - fdpn2) * (fthetan / xxi) ) |
---|
2512 | btra(jpchd) = b0 * ( & |
---|
2513 | + ((frd * fprd * zphd) - fgmepd - fdpd - fdpd2) * (fthetad / xxi) ) |
---|
2514 | !! |
---|
2515 | !!---------------------------------------------------------------------- |
---|
2516 | !! phytoplankton |
---|
2517 | btra(jpphn) = b0 * ( & |
---|
2518 | + (fprn * zphn) - fgmipn - fgmepn - fdpn - fdpn2 ) |
---|
2519 | btra(jpphd) = b0 * ( & |
---|
2520 | + (fprd * zphd) - fgmepd - fdpd - fdpd2 ) |
---|
2521 | btra(jppds) = b0 * ( & |
---|
2522 | + (fprds * zpds) - fgmepds - fdpds - fsdiss - fdpds2 ) |
---|
2523 | !! |
---|
2524 | !!---------------------------------------------------------------------- |
---|
2525 | !! zooplankton |
---|
2526 | btra(jpzmi) = b0 * ( & |
---|
2527 | + fmigrow - fgmezmi - fdzmi - fdzmi2 ) |
---|
2528 | btra(jpzme) = b0 * ( & |
---|
2529 | + fmegrow - fdzme - fdzme2 ) |
---|
2530 | !! |
---|
2531 | !!---------------------------------------------------------------------- |
---|
2532 | !! detritus |
---|
2533 | btra(jpdet) = b0 * ( & |
---|
2534 | + fdpn + ((1.0 - xfdfrac1) * fdpd) & ! mort. losses |
---|
2535 | + fdzmi + ((1.0 - xfdfrac2) * fdzme) & ! mort. losses |
---|
2536 | + ((1.0 - xbetan) * (finmi + finme)) & ! assim. inefficiency |
---|
2537 | - fgmid - fgmed - fdd & ! grazing and remin. |
---|
2538 | + ffast2slown ) ! seafloor fast->slow |
---|
2539 | !! |
---|
2540 | !!---------------------------------------------------------------------- |
---|
2541 | !! dissolved inorganic nitrogen nutrient |
---|
2542 | fn_cons = 0.0 & |
---|
2543 | - (fprn * zphn) - (fprd * zphd) ! primary production |
---|
2544 | fn_prod = 0.0 & |
---|
2545 | + (xphi * (fgmipn + fgmid)) & ! messy feeding remin. |
---|
2546 | + (xphi * (fgmepn + fgmepd + fgmezmi + fgmed)) & ! messy feeding remin. |
---|
2547 | + fmiexcr + fmeexcr + fdd + freminn & ! excretion and remin. |
---|
2548 | + fdpn2 + fdpd2 + fdzmi2 + fdzme2 ! metab. losses |
---|
2549 | !! |
---|
2550 | !! riverine flux |
---|
2551 | if ( jriver_n .gt. 0 ) then |
---|
2552 | f_riv_loc_n = f_riv_n(ji,jj) * friver_dep(jk,(mbathy(ji,jj)-1)) / fthk |
---|
2553 | fn_prod = fn_prod + f_riv_loc_n |
---|
2554 | endif |
---|
2555 | !! |
---|
2556 | !! benthic remineralisation |
---|
2557 | if (jk.eq.(mbathy(ji,jj)-1) .and. jorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2558 | fn_prod = fn_prod + (f_benout_n(ji,jj) / fthk) |
---|
2559 | endif |
---|
2560 | !! |
---|
2561 | btra(jpdin) = b0 * ( & |
---|
2562 | fn_prod + fn_cons ) |
---|
2563 | !! |
---|
2564 | fnit_cons(ji,jj) = fnit_cons(ji,jj) + ( fthk * ( & ! consumption of dissolved nitrogen |
---|
2565 | fn_cons ) ) |
---|
2566 | fnit_prod(ji,jj) = fnit_prod(ji,jj) + ( fthk * ( & ! production of dissolved nitrogen |
---|
2567 | fn_prod ) ) |
---|
2568 | !! |
---|
2569 | !!---------------------------------------------------------------------- |
---|
2570 | !! dissolved silicic acid nutrient |
---|
2571 | fs_cons = 0.0 & |
---|
2572 | - (fprds * zpds) ! opal production |
---|
2573 | fs_prod = 0.0 & |
---|
2574 | + fsdiss & ! opal dissolution |
---|
2575 | + ((1.0 - xfdfrac1) * fdpds) & ! mort. loss |
---|
2576 | + ((1.0 - xfdfrac3) * fgmepds) & ! egestion of grazed Si |
---|
2577 | + freminsi + fdpds2 ! fast diss. and metab. losses |
---|
2578 | !! |
---|
2579 | !! riverine flux |
---|
2580 | if ( jriver_si .gt. 0 ) then |
---|
2581 | f_riv_loc_si = f_riv_si(ji,jj) * friver_dep(jk,(mbathy(ji,jj)-1)) / fthk |
---|
2582 | fs_prod = fs_prod + f_riv_loc_si |
---|
2583 | endif |
---|
2584 | !! |
---|
2585 | !! benthic remineralisation |
---|
2586 | if (jk.eq.(mbathy(ji,jj)-1) .and. jinorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2587 | fs_prod = fs_prod + (f_benout_si(ji,jj) / fthk) |
---|
2588 | endif |
---|
2589 | !! |
---|
2590 | btra(jpsil) = b0 * ( & |
---|
2591 | fs_prod + fs_cons ) |
---|
2592 | !! |
---|
2593 | fsil_cons(ji,jj) = fsil_cons(ji,jj) + ( fthk * ( & ! consumption of dissolved silicon |
---|
2594 | fs_cons ) ) |
---|
2595 | fsil_prod(ji,jj) = fsil_prod(ji,jj) + ( fthk * ( & ! production of dissolved silicon |
---|
2596 | fs_prod ) ) |
---|
2597 | !! |
---|
2598 | !!---------------------------------------------------------------------- |
---|
2599 | !! dissolved "iron" nutrient |
---|
2600 | btra(jpfer) = b0 * ( & |
---|
2601 | + (xrfn * btra(jpdin)) + ffetop + ffebot - ffescav ) |
---|
2602 | |
---|
2603 | # if defined key_roam |
---|
2604 | !! |
---|
2605 | !!---------------------------------------------------------------------- |
---|
2606 | !! AXY (26/11/08): implicit detrital carbon change |
---|
2607 | btra(jpdtc) = b0 * ( & |
---|
2608 | + (xthetapn * fdpn) + ((1.0 - xfdfrac1) * (xthetapd * fdpd)) & ! mort. losses |
---|
2609 | + (xthetazmi * fdzmi) + ((1.0 - xfdfrac2) * (xthetazme * fdzme)) & ! mort. losses |
---|
2610 | + ((1.0 - xbetac) * (ficmi + ficme)) & ! assim. inefficiency |
---|
2611 | - fgmidc - fgmedc - fddc & ! grazing and remin. |
---|
2612 | + ffast2slowc ) ! seafloor fast->slow |
---|
2613 | !! |
---|
2614 | !!---------------------------------------------------------------------- |
---|
2615 | !! dissolved inorganic carbon |
---|
2616 | fc_cons = 0.0 & |
---|
2617 | - (xthetapn * fprn * zphn) - (xthetapd * fprd * zphd) ! primary production |
---|
2618 | fc_prod = 0.0 & |
---|
2619 | + (xthetapn * xphi * fgmipn) + (xphi * fgmidc) & ! messy feeding remin |
---|
2620 | + (xthetapn * xphi * fgmepn) + (xthetapd * xphi * fgmepd) & ! messy feeding remin |
---|
2621 | + (xthetazmi * xphi * fgmezmi) + (xphi * fgmedc) & ! messy feeding remin |
---|
2622 | + fmiresp + fmeresp + fddc + freminc + (xthetapn * fdpn2) & ! resp., remin., losses |
---|
2623 | + (xthetapd * fdpd2) + (xthetazmi * fdzmi2) & ! losses |
---|
2624 | + (xthetazme * fdzme2) ! losses |
---|
2625 | !! |
---|
2626 | !! riverine flux |
---|
2627 | if ( jriver_c .gt. 0 ) then |
---|
2628 | f_riv_loc_c = f_riv_c(ji,jj) * friver_dep(jk,(mbathy(ji,jj)-1)) / fthk |
---|
2629 | fc_prod = fc_prod + f_riv_loc_c |
---|
2630 | endif |
---|
2631 | !! |
---|
2632 | !! benthic remineralisation |
---|
2633 | if (jk.eq.(mbathy(ji,jj)-1) .and. jorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2634 | fc_prod = fc_prod + (f_benout_c(ji,jj) / fthk) |
---|
2635 | endif |
---|
2636 | if (jk.eq.(mbathy(ji,jj)-1) .and. jinorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2637 | fc_prod = fc_prod + (f_benout_ca(ji,jj) / fthk) |
---|
2638 | endif |
---|
2639 | !! |
---|
2640 | !! community respiration (does not include CaCO3 terms - obviously!) |
---|
2641 | fcomm_resp = fc_prod |
---|
2642 | !! |
---|
2643 | !! CaCO3 |
---|
2644 | fc_prod = fc_prod - ftempca + freminca |
---|
2645 | !! |
---|
2646 | !! riverine flux |
---|
2647 | if ( jk .eq. 1 .and. jriver_c .gt. 0 ) then |
---|
2648 | fc_prod = fc_prod + f_riv_c(ji,jj) |
---|
2649 | endif |
---|
2650 | !! |
---|
2651 | btra(jpdic) = b0 * ( & |
---|
2652 | fc_prod + fc_cons ) |
---|
2653 | !! |
---|
2654 | fcar_cons(ji,jj) = fcar_cons(ji,jj) + ( fthk * ( & ! consumption of dissolved carbon |
---|
2655 | fc_cons ) ) |
---|
2656 | fcar_prod(ji,jj) = fcar_prod(ji,jj) + ( fthk * ( & ! production of dissolved carbon |
---|
2657 | fc_prod ) ) |
---|
2658 | !! |
---|
2659 | !!---------------------------------------------------------------------- |
---|
2660 | !! alkalinity |
---|
2661 | fa_prod = 0.0 & |
---|
2662 | + (2.0 * freminca) ! CaCO3 dissolution |
---|
2663 | fa_cons = 0.0 & |
---|
2664 | - (2.0 * ftempca) ! CaCO3 production |
---|
2665 | !! |
---|
2666 | !! riverine flux |
---|
2667 | if ( jriver_alk .gt. 0 ) then |
---|
2668 | f_riv_loc_alk = f_riv_alk(ji,jj) * friver_dep(jk,(mbathy(ji,jj)-1)) / fthk |
---|
2669 | fa_prod = fa_prod + f_riv_loc_alk |
---|
2670 | endif |
---|
2671 | !! |
---|
2672 | !! benthic remineralisation |
---|
2673 | if (jk.eq.(mbathy(ji,jj)-1) .and. jinorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2674 | fa_prod = fa_prod + (2.0 * f_benout_ca(ji,jj) / fthk) |
---|
2675 | endif |
---|
2676 | !! |
---|
2677 | btra(jpalk) = b0 * ( & |
---|
2678 | fa_prod + fa_cons ) |
---|
2679 | !! |
---|
2680 | !!---------------------------------------------------------------------- |
---|
2681 | !! oxygen (has protection at low O2 concentrations; OCMIP-2 style) |
---|
2682 | fo2_prod = 0.0 & |
---|
2683 | + (xthetanit * fprn * zphn) & ! Pn primary production, N |
---|
2684 | + (xthetanit * fprd * zphd) & ! Pd primary production, N |
---|
2685 | + (xthetarem * xthetapn * fprn * zphn) & ! Pn primary production, C |
---|
2686 | + (xthetarem * xthetapd * fprd * zphd) ! Pd primary production, C |
---|
2687 | fo2_ncons = 0.0 & |
---|
2688 | - (xthetanit * xphi * fgmipn) & ! Pn messy feeding remin., N |
---|
2689 | - (xthetanit * xphi * fgmid) & ! D messy feeding remin., N |
---|
2690 | - (xthetanit * xphi * fgmepn) & ! Pn messy feeding remin., N |
---|
2691 | - (xthetanit * xphi * fgmepd) & ! Pd messy feeding remin., N |
---|
2692 | - (xthetanit * xphi * fgmezmi) & ! Zi messy feeding remin., N |
---|
2693 | - (xthetanit * xphi * fgmed) & ! D messy feeding remin., N |
---|
2694 | - (xthetanit * fmiexcr) & ! microzoo excretion, N |
---|
2695 | - (xthetanit * fmeexcr) & ! mesozoo excretion, N |
---|
2696 | - (xthetanit * fdd) & ! slow detritus remin., N |
---|
2697 | - (xthetanit * freminn) & ! fast detritus remin., N |
---|
2698 | - (xthetanit * fdpn2) & ! Pn losses, N |
---|
2699 | - (xthetanit * fdpd2) & ! Pd losses, N |
---|
2700 | - (xthetanit * fdzmi2) & ! Zmi losses, N |
---|
2701 | - (xthetanit * fdzme2) ! Zme losses, N |
---|
2702 | !! |
---|
2703 | !! benthic remineralisation |
---|
2704 | if (jk.eq.(mbathy(ji,jj)-1) .and. jorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2705 | fo2_ncons = fo2_ncons - (xthetanit * f_benout_n(ji,jj) / fthk) |
---|
2706 | endif |
---|
2707 | fo2_ccons = 0.0 & |
---|
2708 | - (xthetarem * xthetapn * xphi * fgmipn) & ! Pn messy feeding remin., C |
---|
2709 | - (xthetarem * xphi * fgmidc) & ! D messy feeding remin., C |
---|
2710 | - (xthetarem * xthetapn * xphi * fgmepn) & ! Pn messy feeding remin., C |
---|
2711 | - (xthetarem * xthetapd * xphi * fgmepd) & ! Pd messy feeding remin., C |
---|
2712 | - (xthetarem * xthetazmi * xphi * fgmezmi) & ! Zi messy feeding remin., C |
---|
2713 | - (xthetarem * xphi * fgmedc) & ! D messy feeding remin., C |
---|
2714 | - (xthetarem * fmiresp) & ! microzoo respiration, C |
---|
2715 | - (xthetarem * fmeresp) & ! mesozoo respiration, C |
---|
2716 | - (xthetarem * fddc) & ! slow detritus remin., C |
---|
2717 | - (xthetarem * freminc) & ! fast detritus remin., C |
---|
2718 | - (xthetarem * xthetapn * fdpn2) & ! Pn losses, C |
---|
2719 | - (xthetarem * xthetapd * fdpd2) & ! Pd losses, C |
---|
2720 | - (xthetarem * xthetazmi * fdzmi2) & ! Zmi losses, C |
---|
2721 | - (xthetarem * xthetazme * fdzme2) ! Zme losses, C |
---|
2722 | !! |
---|
2723 | !! benthic remineralisation |
---|
2724 | if (jk.eq.(mbathy(ji,jj)-1) .and. jorgben.eq.1 .and. ibenthic.eq.1) then |
---|
2725 | fo2_ccons = fo2_ccons - (xthetarem * f_benout_c(ji,jj) / fthk) |
---|
2726 | endif |
---|
2727 | fo2_cons = fo2_ncons + fo2_ccons |
---|
2728 | !! |
---|
2729 | !! is this a suboxic zone? |
---|
2730 | if (zoxy.lt.xo2min) then ! deficient O2; production fluxes only |
---|
2731 | btra(jpoxy) = b0 * ( & |
---|
2732 | fo2_prod ) |
---|
2733 | foxy_prod(ji,jj) = foxy_prod(ji,jj) + ( fthk * fo2_prod ) |
---|
2734 | foxy_anox(ji,jj) = foxy_anox(ji,jj) + ( fthk * fo2_cons ) |
---|
2735 | else ! sufficient O2; production + consumption fluxes |
---|
2736 | btra(jpoxy) = b0 * ( & |
---|
2737 | fo2_prod + fo2_cons ) |
---|
2738 | foxy_prod(ji,jj) = foxy_prod(ji,jj) + ( fthk * fo2_prod ) |
---|
2739 | foxy_cons(ji,jj) = foxy_cons(ji,jj) + ( fthk * fo2_cons ) |
---|
2740 | endif |
---|
2741 | !! |
---|
2742 | !! air-sea fluxes (if this is the surface box) |
---|
2743 | if (jk.eq.1) then |
---|
2744 | !! |
---|
2745 | !! CO2 flux |
---|
2746 | btra(jpdic) = btra(jpdic) + (b0 * f_co2flux) |
---|
2747 | !! |
---|
2748 | !! O2 flux (mol/m3/s -> mmol/m3/d) |
---|
2749 | btra(jpoxy) = btra(jpoxy) + (b0 * f_o2flux) |
---|
2750 | endif |
---|
2751 | # endif |
---|
2752 | |
---|
2753 | # if defined key_debug_medusa |
---|
2754 | !! report state variable fluxes (not including fast-sinking detritus) |
---|
2755 | if (idf.eq.1.AND.idfval.eq.1) then |
---|
2756 | IF (lwp) write (numout,*) '------------------------------' |
---|
2757 | IF (lwp) write (numout,*) 'btra(jpchn)(',jk,') = ', btra(jpchn) |
---|
2758 | IF (lwp) write (numout,*) 'btra(jpchd)(',jk,') = ', btra(jpchd) |
---|
2759 | IF (lwp) write (numout,*) 'btra(jpphn)(',jk,') = ', btra(jpphn) |
---|
2760 | IF (lwp) write (numout,*) 'btra(jpphd)(',jk,') = ', btra(jpphd) |
---|
2761 | IF (lwp) write (numout,*) 'btra(jppds)(',jk,') = ', btra(jppds) |
---|
2762 | IF (lwp) write (numout,*) 'btra(jpzmi)(',jk,') = ', btra(jpzmi) |
---|
2763 | IF (lwp) write (numout,*) 'btra(jpzme)(',jk,') = ', btra(jpzme) |
---|
2764 | IF (lwp) write (numout,*) 'btra(jpdet)(',jk,') = ', btra(jpdet) |
---|
2765 | IF (lwp) write (numout,*) 'btra(jpdin)(',jk,') = ', btra(jpdin) |
---|
2766 | IF (lwp) write (numout,*) 'btra(jpsil)(',jk,') = ', btra(jpsil) |
---|
2767 | IF (lwp) write (numout,*) 'btra(jpfer)(',jk,') = ', btra(jpfer) |
---|
2768 | # if defined key_roam |
---|
2769 | IF (lwp) write (numout,*) 'btra(jpdtc)(',jk,') = ', btra(jpdtc) |
---|
2770 | IF (lwp) write (numout,*) 'btra(jpdic)(',jk,') = ', btra(jpdic) |
---|
2771 | IF (lwp) write (numout,*) 'btra(jpalk)(',jk,') = ', btra(jpalk) |
---|
2772 | IF (lwp) write (numout,*) 'btra(jpoxy)(',jk,') = ', btra(jpoxy) |
---|
2773 | # endif |
---|
2774 | endif |
---|
2775 | # endif |
---|
2776 | |
---|
2777 | !!---------------------------------------------------------------------- |
---|
2778 | !! Integrate calculated fluxes for mass balance |
---|
2779 | !!---------------------------------------------------------------------- |
---|
2780 | !! |
---|
2781 | !! === nitrogen === |
---|
2782 | fflx_n(ji,jj) = fflx_n(ji,jj) + & |
---|
2783 | fthk * ( btra(jpphn) + btra(jpphd) + btra(jpzmi) + btra(jpzme) + btra(jpdet) + btra(jpdin) ) |
---|
2784 | !! === silicon === |
---|
2785 | fflx_si(ji,jj) = fflx_si(ji,jj) + & |
---|
2786 | fthk * ( btra(jppds) + btra(jpsil) ) |
---|
2787 | !! === iron === |
---|
2788 | fflx_fe(ji,jj) = fflx_fe(ji,jj) + & |
---|
2789 | fthk * ( ( xrfn * ( btra(jpphn) + btra(jpphd) + btra(jpzmi) + btra(jpzme) + btra(jpdet)) ) + btra(jpfer) ) |
---|
2790 | # if defined key_roam |
---|
2791 | !! === carbon === |
---|
2792 | fflx_c(ji,jj) = fflx_c(ji,jj) + & |
---|
2793 | fthk * ( (xthetapn * btra(jpphn)) + (xthetapd * btra(jpphd)) + & |
---|
2794 | (xthetazmi * btra(jpzmi)) + (xthetazme * btra(jpzme)) + btra(jpdtc) + btra(jpdic) ) |
---|
2795 | !! === alkalinity === |
---|
2796 | fflx_a(ji,jj) = fflx_a(ji,jj) + & |
---|
2797 | fthk * ( btra(jpalk) ) |
---|
2798 | !! === oxygen === |
---|
2799 | fflx_o2(ji,jj) = fflx_o2(ji,jj) + & |
---|
2800 | fthk * ( btra(jpoxy) ) |
---|
2801 | # endif |
---|
2802 | |
---|
2803 | !!---------------------------------------------------------------------- |
---|
2804 | !! Apply calculated tracer fluxes |
---|
2805 | !!---------------------------------------------------------------------- |
---|
2806 | !! |
---|
2807 | !! units: [unit of tracer] per second (fluxes are calculated above per day) |
---|
2808 | !! |
---|
2809 | ibio_switch = 1 |
---|
2810 | # if defined key_gulf_finland |
---|
2811 | !! AXY (17/05/13): fudge in a Gulf of Finland correction; uses longitude- |
---|
2812 | !! latitude range to establish if this is a Gulf of Finland |
---|
2813 | !! grid cell; if so, then BGC fluxes are ignored (though |
---|
2814 | !! still calculated); for reference, this is meant to be a |
---|
2815 | !! temporary fix to see if all of my problems can be done |
---|
2816 | !! away with if I switch off BGC fluxes in the Gulf of |
---|
2817 | !! Finland, which currently appears the source of trouble |
---|
2818 | if ( flonx.gt.24.7 .and. flonx.lt.27.8 .and. & |
---|
2819 | & flatx.gt.59.2 .and. flatx.lt.60.2 ) then |
---|
2820 | ibio_switch = 0 |
---|
2821 | endif |
---|
2822 | # endif |
---|
2823 | if (ibio_switch.eq.1) then |
---|
2824 | tra(ji,jj,jk,jpchn) = tra(ji,jj,jk,jpchn) + (btra(jpchn) / 86400.) |
---|
2825 | tra(ji,jj,jk,jpchd) = tra(ji,jj,jk,jpchd) + (btra(jpchd) / 86400.) |
---|
2826 | tra(ji,jj,jk,jpphn) = tra(ji,jj,jk,jpphn) + (btra(jpphn) / 86400.) |
---|
2827 | tra(ji,jj,jk,jpphd) = tra(ji,jj,jk,jpphd) + (btra(jpphd) / 86400.) |
---|
2828 | tra(ji,jj,jk,jppds) = tra(ji,jj,jk,jppds) + (btra(jppds) / 86400.) |
---|
2829 | tra(ji,jj,jk,jpzmi) = tra(ji,jj,jk,jpzmi) + (btra(jpzmi) / 86400.) |
---|
2830 | tra(ji,jj,jk,jpzme) = tra(ji,jj,jk,jpzme) + (btra(jpzme) / 86400.) |
---|
2831 | tra(ji,jj,jk,jpdet) = tra(ji,jj,jk,jpdet) + (btra(jpdet) / 86400.) |
---|
2832 | tra(ji,jj,jk,jpdin) = tra(ji,jj,jk,jpdin) + (btra(jpdin) / 86400.) |
---|
2833 | tra(ji,jj,jk,jpsil) = tra(ji,jj,jk,jpsil) + (btra(jpsil) / 86400.) |
---|
2834 | tra(ji,jj,jk,jpfer) = tra(ji,jj,jk,jpfer) + (btra(jpfer) / 86400.) |
---|
2835 | # if defined key_roam |
---|
2836 | tra(ji,jj,jk,jpdtc) = tra(ji,jj,jk,jpdtc) + (btra(jpdtc) / 86400.) |
---|
2837 | tra(ji,jj,jk,jpdic) = tra(ji,jj,jk,jpdic) + (btra(jpdic) / 86400.) |
---|
2838 | tra(ji,jj,jk,jpalk) = tra(ji,jj,jk,jpalk) + (btra(jpalk) / 86400.) |
---|
2839 | tra(ji,jj,jk,jpoxy) = tra(ji,jj,jk,jpoxy) + (btra(jpoxy) / 86400.) |
---|
2840 | # endif |
---|
2841 | endif |
---|
2842 | |
---|
2843 | # if defined key_axy_nancheck |
---|
2844 | !!---------------------------------------------------------------------- |
---|
2845 | !! Check calculated tracer fluxes |
---|
2846 | !!---------------------------------------------------------------------- |
---|
2847 | !! |
---|
2848 | DO jn = 1,jptra |
---|
2849 | fq0 = btra(jn) |
---|
2850 | !! AXY (30/01/14): "isnan" problem on HECTOR |
---|
2851 | !! if (fq0 /= fq0 ) then |
---|
2852 | if ( ieee_is_nan( fq0 ) ) then |
---|
2853 | !! there's a NaN here |
---|
2854 | if (lwp) write(numout,*) 'NAN detected in btra(', ji, ',', & |
---|
2855 | & jj, ',', jk, ',', jn, ') at time', kt |
---|
2856 | CALL ctl_stop( 'trcbio_medusa, NAN in btra field' ) |
---|
2857 | endif |
---|
2858 | ENDDO |
---|
2859 | DO jn = 1,jptra |
---|
2860 | fq0 = tra(ji,jj,jk,jn) |
---|
2861 | !! AXY (30/01/14): "isnan" problem on HECTOR |
---|
2862 | !! if (fq0 /= fq0 ) then |
---|
2863 | if ( ieee_is_nan( fq0 ) ) then |
---|
2864 | !! there's a NaN here |
---|
2865 | if (lwp) write(numout,*) 'NAN detected in tra(', ji, ',', & |
---|
2866 | & jj, ',', jk, ',', jn, ') at time', kt |
---|
2867 | CALL ctl_stop( 'trcbio_medusa, NAN in tra field' ) |
---|
2868 | endif |
---|
2869 | ENDDO |
---|
2870 | CALL flush(numout) |
---|
2871 | # endif |
---|
2872 | |
---|
2873 | !!---------------------------------------------------------------------- |
---|
2874 | !! Check model conservation |
---|
2875 | !! these terms merely sum up the tendency terms of the relevant |
---|
2876 | !! state variables, which should sum to zero; the iron cycle is |
---|
2877 | !! complicated by fluxes that add (aeolian deposition and seafloor |
---|
2878 | !! remineralisation) and remove (scavenging) dissolved iron from |
---|
2879 | !! the model (i.e. the sum of iron fluxes is unlikely to be zero) |
---|
2880 | !!---------------------------------------------------------------------- |
---|
2881 | !! |
---|
2882 | !! fnit0 = btra(jpphn) + btra(jpphd) + btra(jpzmi) + btra(jpzme) + btra(jpdet) + btra(jpdin) ! + ftempn |
---|
2883 | !! fsil0 = btra(jppds) + btra(jpsil) ! + ftempsi |
---|
2884 | !! ffer0 = (xrfn * fnit0) + btra(jpfer) |
---|
2885 | # if defined key_roam |
---|
2886 | !! fcar0 = 0. |
---|
2887 | !! falk0 = 0. |
---|
2888 | !! foxy0 = 0. |
---|
2889 | # endif |
---|
2890 | !! |
---|
2891 | !! if (kt/240*240.eq.kt) then |
---|
2892 | !! if (ji.eq.2.and.jj.eq.2.and.jk.eq.1) then |
---|
2893 | !! IF (lwp) write (*,*) '*******!MEDUSA Conservation!*******',kt |
---|
2894 | # if defined key_roam |
---|
2895 | !! IF (lwp) write (*,*) fnit0,fsil0,ffer0,fcar0,falk0,foxy0 |
---|
2896 | # else |
---|
2897 | !! IF (lwp) write (*,*) fnit0,fsil0,ffer0 |
---|
2898 | # endif |
---|
2899 | !! endif |
---|
2900 | !! endif |
---|
2901 | |
---|
2902 | # if defined key_trc_diabio |
---|
2903 | !!====================================================================== |
---|
2904 | !! LOCAL GRID CELL DIAGNOSTICS |
---|
2905 | !!====================================================================== |
---|
2906 | !! |
---|
2907 | !!---------------------------------------------------------------------- |
---|
2908 | !! Full diagnostics key_trc_diabio: |
---|
2909 | !! LOBSTER and PISCES support full diagnistics option key_trc_diabio |
---|
2910 | !! which gives an option of FULL output of biological sourses and sinks. |
---|
2911 | !! I cannot see any reason for doing this. If needed, it can be done |
---|
2912 | !! as shown below. |
---|
2913 | !!---------------------------------------------------------------------- |
---|
2914 | !! |
---|
2915 | IF(lwp) WRITE(numout,*) ' MEDUSA does not support key_trc_diabio' |
---|
2916 | !! trbio(ji,jj,jk, 1) = fprn |
---|
2917 | # endif |
---|
2918 | |
---|
2919 | IF( ln_diatrc ) THEN |
---|
2920 | !!---------------------------------------------------------------------- |
---|
2921 | !! Prepare 2D diagnostics |
---|
2922 | !!---------------------------------------------------------------------- |
---|
2923 | !! |
---|
2924 | !! if ((kt / 240*240).eq.kt) then |
---|
2925 | !! IF (lwp) write (*,*) '*******!MEDUSA DIAADD!*******',kt |
---|
2926 | !! endif |
---|
2927 | trc2d(ji,jj,1) = trc2d(ji,jj,1) + ftot_n !! nitrogen inventory |
---|
2928 | trc2d(ji,jj,2) = trc2d(ji,jj,2) + ftot_si !! silicon inventory |
---|
2929 | trc2d(ji,jj,3) = trc2d(ji,jj,3) + ftot_fe !! iron inventory |
---|
2930 | trc2d(ji,jj,4) = trc2d(ji,jj,4) + (fprn * zphn * fthk) !! non-diatom production |
---|
2931 | trc2d(ji,jj,5) = trc2d(ji,jj,5) + (fdpn * fthk) !! non-diatom non-grazing losses |
---|
2932 | trc2d(ji,jj,6) = trc2d(ji,jj,6) + (fprd * zphd * fthk) !! diatom production |
---|
2933 | trc2d(ji,jj,7) = trc2d(ji,jj,7) + (fdpd * fthk) !! diatom non-grazing losses |
---|
2934 | !! diagnostic field 8 is (ostensibly) supplied by trcsed.F |
---|
2935 | trc2d(ji,jj,9) = trc2d(ji,jj,9) + (fprds * zpds * fthk) !! diatom silicon production |
---|
2936 | trc2d(ji,jj,10) = trc2d(ji,jj,10) + (fsdiss * fthk) !! diatom silicon dissolution |
---|
2937 | trc2d(ji,jj,11) = trc2d(ji,jj,11) + (fgmipn * fthk) !! microzoo grazing on non-diatoms |
---|
2938 | trc2d(ji,jj,12) = trc2d(ji,jj,12) + (fgmid * fthk) !! microzoo grazing on detrital nitrogen |
---|
2939 | trc2d(ji,jj,13) = trc2d(ji,jj,13) + (fdzmi * fthk) !! microzoo non-grazing losses |
---|
2940 | trc2d(ji,jj,14) = trc2d(ji,jj,14) + (fgmepn * fthk) !! mesozoo grazing on non-diatoms |
---|
2941 | trc2d(ji,jj,15) = trc2d(ji,jj,15) + (fgmepd * fthk) !! mesozoo grazing on diatoms |
---|
2942 | trc2d(ji,jj,16) = trc2d(ji,jj,16) + (fgmezmi * fthk) !! mesozoo grazing on microzoo |
---|
2943 | trc2d(ji,jj,17) = trc2d(ji,jj,17) + (fgmed * fthk) !! mesozoo grazing on detrital nitrogen |
---|
2944 | trc2d(ji,jj,18) = trc2d(ji,jj,18) + (fdzme * fthk) !! mesozoo non-grazing losses |
---|
2945 | !! diagnostic field 19 is (ostensibly) supplied by trcexp.F |
---|
2946 | trc2d(ji,jj,20) = trc2d(ji,jj,20) + (fslown * fthk) !! slow sinking detritus N production |
---|
2947 | trc2d(ji,jj,21) = trc2d(ji,jj,21) + (fdd * fthk) !! detrital remineralisation |
---|
2948 | trc2d(ji,jj,22) = trc2d(ji,jj,22) + (ffetop * fthk) !! aeolian iron addition |
---|
2949 | trc2d(ji,jj,23) = trc2d(ji,jj,23) + (ffebot * fthk) !! seafloor iron addition |
---|
2950 | trc2d(ji,jj,24) = trc2d(ji,jj,24) + (ffescav * fthk) !! "free" iron scavenging |
---|
2951 | trc2d(ji,jj,25) = trc2d(ji,jj,25) + (fjln * zphn * fthk) !! non-diatom J limitation term |
---|
2952 | trc2d(ji,jj,26) = trc2d(ji,jj,26) + (fnln * zphn * fthk) !! non-diatom N limitation term |
---|
2953 | trc2d(ji,jj,27) = trc2d(ji,jj,27) + (ffln * zphn * fthk) !! non-diatom Fe limitation term |
---|
2954 | trc2d(ji,jj,28) = trc2d(ji,jj,28) + (fjld * zphd * fthk) !! diatom J limitation term |
---|
2955 | trc2d(ji,jj,29) = trc2d(ji,jj,29) + (fnld * zphd * fthk) !! diatom N limitation term |
---|
2956 | trc2d(ji,jj,30) = trc2d(ji,jj,30) + (ffld * zphd * fthk) !! diatom Fe limitation term |
---|
2957 | trc2d(ji,jj,31) = trc2d(ji,jj,31) + (fsld2 * zphd * fthk) !! diatom Si limitation term |
---|
2958 | trc2d(ji,jj,32) = trc2d(ji,jj,32) + (fsld * zphd * fthk) !! diatom Si uptake limitation term |
---|
2959 | if (jk.eq.i0100) trc2d(ji,jj,33) = fslownflux !! slow detritus flux at 100 m |
---|
2960 | if (jk.eq.i0200) trc2d(ji,jj,34) = fslownflux !! slow detritus flux at 200 m |
---|
2961 | if (jk.eq.i0500) trc2d(ji,jj,35) = fslownflux !! slow detritus flux at 500 m |
---|
2962 | if (jk.eq.i1000) trc2d(ji,jj,36) = fslownflux !! slow detritus flux at 1000 m |
---|
2963 | trc2d(ji,jj,37) = trc2d(ji,jj,37) + fregen !! non-fast N full column regeneration |
---|
2964 | trc2d(ji,jj,38) = trc2d(ji,jj,38) + fregensi !! non-fast Si full column regeneration |
---|
2965 | if (jk.eq.i0100) trc2d(ji,jj,39) = trc2d(ji,jj,37) !! non-fast N regeneration to 100 m |
---|
2966 | if (jk.eq.i0200) trc2d(ji,jj,40) = trc2d(ji,jj,37) !! non-fast N regeneration to 200 m |
---|
2967 | if (jk.eq.i0500) trc2d(ji,jj,41) = trc2d(ji,jj,37) !! non-fast N regeneration to 500 m |
---|
2968 | if (jk.eq.i1000) trc2d(ji,jj,42) = trc2d(ji,jj,37) !! non-fast N regeneration to 1000 m |
---|
2969 | trc2d(ji,jj,43) = trc2d(ji,jj,43) + (ftempn * fthk) !! fast sinking detritus N production |
---|
2970 | trc2d(ji,jj,44) = trc2d(ji,jj,44) + (ftempsi * fthk) !! fast sinking detritus Si production |
---|
2971 | trc2d(ji,jj,45) = trc2d(ji,jj,45) + (ftempfe * fthk) !! fast sinking detritus Fe production |
---|
2972 | trc2d(ji,jj,46) = trc2d(ji,jj,46) + (ftempc * fthk) !! fast sinking detritus C production |
---|
2973 | trc2d(ji,jj,47) = trc2d(ji,jj,47) + (ftempca * fthk) !! fast sinking detritus CaCO3 production |
---|
2974 | if (jk.eq.i0100) trc2d(ji,jj,48) = ffastn(ji,jj) !! fast detritus N flux at 100 m |
---|
2975 | if (jk.eq.i0200) trc2d(ji,jj,49) = ffastn(ji,jj) !! fast detritus N flux at 200 m |
---|
2976 | if (jk.eq.i0500) trc2d(ji,jj,50) = ffastn(ji,jj) !! fast detritus N flux at 500 m |
---|
2977 | if (jk.eq.i1000) trc2d(ji,jj,51) = ffastn(ji,jj) !! fast detritus N flux at 1000 m |
---|
2978 | if (jk.eq.i0100) trc2d(ji,jj,52) = fregenfast(ji,jj) !! N regeneration to 100 m |
---|
2979 | if (jk.eq.i0200) trc2d(ji,jj,53) = fregenfast(ji,jj) !! N regeneration to 200 m |
---|
2980 | if (jk.eq.i0500) trc2d(ji,jj,54) = fregenfast(ji,jj) !! N regeneration to 500 m |
---|
2981 | if (jk.eq.i1000) trc2d(ji,jj,55) = fregenfast(ji,jj) !! N regeneration to 1000 m |
---|
2982 | if (jk.eq.i0100) trc2d(ji,jj,56) = ffastsi(ji,jj) !! fast detritus Si flux at 100 m |
---|
2983 | if (jk.eq.i0200) trc2d(ji,jj,57) = ffastsi(ji,jj) !! fast detritus Si flux at 200 m |
---|
2984 | if (jk.eq.i0500) trc2d(ji,jj,58) = ffastsi(ji,jj) !! fast detritus Si flux at 500 m |
---|
2985 | if (jk.eq.i1000) trc2d(ji,jj,59) = ffastsi(ji,jj) !! fast detritus Si flux at 1000 m |
---|
2986 | if (jk.eq.i0100) trc2d(ji,jj,60) = fregenfastsi(ji,jj) !! Si regeneration to 100 m |
---|
2987 | if (jk.eq.i0200) trc2d(ji,jj,61) = fregenfastsi(ji,jj) !! Si regeneration to 200 m |
---|
2988 | if (jk.eq.i0500) trc2d(ji,jj,62) = fregenfastsi(ji,jj) !! Si regeneration to 500 m |
---|
2989 | if (jk.eq.i1000) trc2d(ji,jj,63) = fregenfastsi(ji,jj) !! Si regeneration to 1000 m |
---|
2990 | trc2d(ji,jj,64) = trc2d(ji,jj,64) + (freminn * fthk) !! sum of fast-sinking N fluxes |
---|
2991 | trc2d(ji,jj,65) = trc2d(ji,jj,65) + (freminsi * fthk) !! sum of fast-sinking Si fluxes |
---|
2992 | trc2d(ji,jj,66) = trc2d(ji,jj,66) + (freminfe * fthk) !! sum of fast-sinking Fe fluxes |
---|
2993 | trc2d(ji,jj,67) = trc2d(ji,jj,67) + (freminc * fthk) !! sum of fast-sinking C fluxes |
---|
2994 | trc2d(ji,jj,68) = trc2d(ji,jj,68) + (freminca * fthk) !! sum of fast-sinking Ca fluxes |
---|
2995 | if (jk.eq.(mbathy(ji,jj)-1)) then |
---|
2996 | trc2d(ji,jj,69) = fsedn !! N sedimentation flux |
---|
2997 | trc2d(ji,jj,70) = fsedsi !! Si sedimentation flux |
---|
2998 | trc2d(ji,jj,71) = fsedfe !! Fe sedimentation flux |
---|
2999 | trc2d(ji,jj,72) = fsedc !! C sedimentation flux |
---|
3000 | trc2d(ji,jj,73) = fsedca !! Ca sedimentation flux |
---|
3001 | endif |
---|
3002 | if (jk.eq.1) trc2d(ji,jj,74) = qsr(ji,jj) |
---|
3003 | if (jk.eq.1) trc2d(ji,jj,75) = xpar(ji,jj,jk) |
---|
3004 | !! if (jk.eq.1) trc2d(ji,jj,75) = real(iters) |
---|
3005 | !! diagnostic fields 76 to 80 calculated below |
---|
3006 | trc2d(ji,jj,81) = trc2d(ji,jj,81) + fprn_ml !! mixed layer non-diatom production |
---|
3007 | trc2d(ji,jj,82) = trc2d(ji,jj,82) + fprd_ml !! mixed layer diatom production |
---|
3008 | # if defined key_gulf_finland |
---|
3009 | if (jk.eq.1) trc2d(ji,jj,83) = real(ibio_switch) !! Gulf of Finland check |
---|
3010 | # else |
---|
3011 | trc2d(ji,jj,83) = ocal_ccd(ji,jj) !! calcite CCD depth |
---|
3012 | # endif |
---|
3013 | trc2d(ji,jj,84) = fccd(ji,jj) !! last model level above calcite CCD depth |
---|
3014 | if (jk.eq.1) trc2d(ji,jj,85) = xFree !! surface "free" iron |
---|
3015 | if (jk.eq.i0200) trc2d(ji,jj,86) = xFree !! "free" iron at 100 m |
---|
3016 | if (jk.eq.i0200) trc2d(ji,jj,87) = xFree !! "free" iron at 200 m |
---|
3017 | if (jk.eq.i0500) trc2d(ji,jj,88) = xFree !! "free" iron at 500 m |
---|
3018 | if (jk.eq.i1000) trc2d(ji,jj,89) = xFree !! "free" iron at 1000 m |
---|
3019 | !! AXY (27/06/12): extract "euphotic depth" |
---|
3020 | if (jk.eq.1) trc2d(ji,jj,90) = xze(ji,jj) |
---|
3021 | !! |
---|
3022 | ftot_pn(ji,jj) = ftot_pn(ji,jj) + (zphn * fthk) !! vertical integral non-diatom phytoplankton |
---|
3023 | ftot_pd(ji,jj) = ftot_pd(ji,jj) + (zphd * fthk) !! vertical integral diatom phytoplankton |
---|
3024 | ftot_zmi(ji,jj) = ftot_zmi(ji,jj) + (zzmi * fthk) !! vertical integral microzooplankton |
---|
3025 | ftot_zme(ji,jj) = ftot_zme(ji,jj) + (zzme * fthk) !! vertical integral mesozooplankton |
---|
3026 | ftot_det(ji,jj) = ftot_det(ji,jj) + (zdet * fthk) !! vertical integral slow detritus, nitrogen |
---|
3027 | ftot_dtc(ji,jj) = ftot_dtc(ji,jj) + (zdtc * fthk) !! vertical integral slow detritus, carbon |
---|
3028 | # if defined key_roam |
---|
3029 | !! ROAM provisionally has access to a further 20 2D diagnostics |
---|
3030 | if (jk .eq. 1) then |
---|
3031 | trc2d(ji,jj,91) = trc2d(ji,jj,91) + f_wind !! surface wind |
---|
3032 | trc2d(ji,jj,92) = trc2d(ji,jj,92) + f_pco2a !! atmospheric pCO2 |
---|
3033 | trc2d(ji,jj,93) = trc2d(ji,jj,93) + f_ph !! ocean pH |
---|
3034 | trc2d(ji,jj,94) = trc2d(ji,jj,94) + f_pco2w !! ocean pCO2 |
---|
3035 | trc2d(ji,jj,95) = trc2d(ji,jj,95) + f_h2co3 !! ocean H2CO3 conc. |
---|
3036 | trc2d(ji,jj,96) = trc2d(ji,jj,96) + f_hco3 !! ocean HCO3 conc. |
---|
3037 | trc2d(ji,jj,97) = trc2d(ji,jj,97) + f_co3 !! ocean CO3 conc. |
---|
3038 | trc2d(ji,jj,98) = trc2d(ji,jj,98) + f_co2flux !! air-sea CO2 flux |
---|
3039 | trc2d(ji,jj,99) = trc2d(ji,jj,99) + f_omcal(ji,jj) !! ocean omega calcite |
---|
3040 | trc2d(ji,jj,100) = trc2d(ji,jj,100) + f_omarg(ji,jj) !! ocean omega aragonite |
---|
3041 | trc2d(ji,jj,101) = trc2d(ji,jj,101) + f_TDIC !! ocean TDIC |
---|
3042 | trc2d(ji,jj,102) = trc2d(ji,jj,102) + f_TALK !! ocean TALK |
---|
3043 | trc2d(ji,jj,103) = trc2d(ji,jj,103) + f_kw660 !! surface kw660 |
---|
3044 | trc2d(ji,jj,104) = trc2d(ji,jj,104) + f_pp0 !! surface pressure |
---|
3045 | trc2d(ji,jj,105) = trc2d(ji,jj,105) + f_o2flux !! air-sea O2 flux |
---|
3046 | trc2d(ji,jj,106) = trc2d(ji,jj,106) + f_o2sat !! ocean O2 saturation |
---|
3047 | trc2d(ji,jj,107) = f2_ccd_cal(ji,jj) !! depth calcite CCD |
---|
3048 | trc2d(ji,jj,108) = f2_ccd_arg(ji,jj) !! depth aragonite CCD |
---|
3049 | endif |
---|
3050 | if (jk .eq. (mbathy(ji,jj)-1)) then |
---|
3051 | trc2d(ji,jj,109) = f3_omcal(ji,jj,jk) !! seafloor omega calcite |
---|
3052 | trc2d(ji,jj,110) = f3_omarg(ji,jj,jk) !! seafloor omega aragonite |
---|
3053 | endif |
---|
3054 | !! diagnostic fields 111 to 117 calculated below |
---|
3055 | if (jk.eq.i0100) trc2d(ji,jj,118) = ffastca(ji,jj)/MAX(ffastc(ji,jj), rsmall) !! rain ratio at 100 m |
---|
3056 | if (jk.eq.i0500) trc2d(ji,jj,119) = ffastca(ji,jj)/MAX(ffastc(ji,jj), rsmall) !! rain ratio at 500 m |
---|
3057 | if (jk.eq.i1000) trc2d(ji,jj,120) = ffastca(ji,jj)/MAX(ffastc(ji,jj), rsmall) !! rain ratio at 1000 m |
---|
3058 | !! AXY (18/01/12): benthic flux diagnostics |
---|
3059 | if (jk.eq.(mbathy(ji,jj)-1)) then |
---|
3060 | trc2d(ji,jj,121) = f_sbenin_n(ji,jj) + f_fbenin_n(ji,jj) |
---|
3061 | trc2d(ji,jj,122) = f_sbenin_fe(ji,jj) + f_fbenin_fe(ji,jj) |
---|
3062 | trc2d(ji,jj,123) = f_sbenin_c(ji,jj) + f_fbenin_c(ji,jj) |
---|
3063 | trc2d(ji,jj,124) = f_fbenin_si(ji,jj) |
---|
3064 | trc2d(ji,jj,125) = f_fbenin_ca(ji,jj) |
---|
3065 | trc2d(ji,jj,126) = f_benout_n(ji,jj) |
---|
3066 | trc2d(ji,jj,127) = f_benout_fe(ji,jj) |
---|
3067 | trc2d(ji,jj,128) = f_benout_c(ji,jj) |
---|
3068 | trc2d(ji,jj,129) = f_benout_si(ji,jj) |
---|
3069 | trc2d(ji,jj,130) = f_benout_ca(ji,jj) |
---|
3070 | endif |
---|
3071 | !! diagnostics fields 131 to 135 calculated below |
---|
3072 | trc2d(ji,jj,136) = f_runoff(ji,jj) |
---|
3073 | !! AXY (19/07/12): amended to allow for riverine nutrient addition below surface |
---|
3074 | trc2d(ji,jj,137) = trc2d(ji,jj,137) + (f_riv_loc_n * fthk) |
---|
3075 | trc2d(ji,jj,138) = trc2d(ji,jj,138) + (f_riv_loc_si * fthk) |
---|
3076 | trc2d(ji,jj,139) = trc2d(ji,jj,139) + (f_riv_loc_c * fthk) |
---|
3077 | trc2d(ji,jj,140) = trc2d(ji,jj,140) + (f_riv_loc_alk * fthk) |
---|
3078 | trc2d(ji,jj,141) = trc2d(ji,jj,141) + (fslowc * fthk) !! slow sinking detritus C production |
---|
3079 | if (jk.eq.i0100) trc2d(ji,jj,142) = fslowcflux !! slow detritus flux at 100 m |
---|
3080 | if (jk.eq.i0200) trc2d(ji,jj,143) = fslowcflux !! slow detritus flux at 200 m |
---|
3081 | if (jk.eq.i0500) trc2d(ji,jj,144) = fslowcflux !! slow detritus flux at 500 m |
---|
3082 | if (jk.eq.i1000) trc2d(ji,jj,145) = fslowcflux !! slow detritus flux at 1000 m |
---|
3083 | trc2d(ji,jj,146) = trc2d(ji,jj,146) + ftot_c !! carbon inventory |
---|
3084 | trc2d(ji,jj,147) = trc2d(ji,jj,147) + ftot_a !! alkalinity inventory |
---|
3085 | trc2d(ji,jj,148) = trc2d(ji,jj,148) + ftot_o2 !! oxygen inventory |
---|
3086 | if (jk.eq.(mbathy(ji,jj)-1)) then |
---|
3087 | trc2d(ji,jj,149) = f_benout_lyso_ca(ji,jj) |
---|
3088 | endif |
---|
3089 | trc2d(ji,jj,150) = trc2d(ji,jj,150) + (fcomm_resp * fthk) !! community respiration |
---|
3090 | !! |
---|
3091 | !! AXY (14/02/14): a Valentines Day gift to BASIN - a shedload of new |
---|
3092 | !! diagnostics that they'll most likely never need! |
---|
3093 | !! (actually, as with all such gifts, I'm giving them |
---|
3094 | !! some things I'd like myself!) |
---|
3095 | !! |
---|
3096 | !! ---------------------------------------------------------------------- |
---|
3097 | !! linear losses |
---|
3098 | !! non-diatom |
---|
3099 | trc2d(ji,jj,151) = trc2d(ji,jj,151) + (fdpn2 * fthk) |
---|
3100 | !! diatom |
---|
3101 | trc2d(ji,jj,152) = trc2d(ji,jj,152) + (fdpd2 * fthk) |
---|
3102 | !! microzooplankton |
---|
3103 | trc2d(ji,jj,153) = trc2d(ji,jj,153) + (fdzmi2 * fthk) |
---|
3104 | !! mesozooplankton |
---|
3105 | trc2d(ji,jj,154) = trc2d(ji,jj,154) + (fdzme2 * fthk) |
---|
3106 | !! ---------------------------------------------------------------------- |
---|
3107 | !! microzooplankton grazing |
---|
3108 | !! microzooplankton messy -> N |
---|
3109 | trc2d(ji,jj,155) = trc2d(ji,jj,155) + (xphi * (fgmipn + fgmid) * fthk) |
---|
3110 | !! microzooplankton messy -> D |
---|
3111 | trc2d(ji,jj,156) = trc2d(ji,jj,156) + ((1. - xbetan) * finmi * fthk) |
---|
3112 | !! microzooplankton messy -> DIC |
---|
3113 | trc2d(ji,jj,157) = trc2d(ji,jj,157) + (xphi * ((xthetapn * fgmipn) + fgmidc) * fthk) |
---|
3114 | !! microzooplankton messy -> Dc |
---|
3115 | trc2d(ji,jj,158) = trc2d(ji,jj,158) + ((1. - xbetac) * ficmi * fthk) |
---|
3116 | !! microzooplankton excretion |
---|
3117 | trc2d(ji,jj,159) = trc2d(ji,jj,159) + (fmiexcr * fthk) |
---|
3118 | !! microzooplankton respiration |
---|
3119 | trc2d(ji,jj,160) = trc2d(ji,jj,160) + (fmiresp * fthk) |
---|
3120 | !! microzooplankton growth |
---|
3121 | trc2d(ji,jj,161) = trc2d(ji,jj,161) + (fmigrow * fthk) |
---|
3122 | !! ---------------------------------------------------------------------- |
---|
3123 | !! mesozooplankton grazing |
---|
3124 | !! mesozooplankton messy -> N |
---|
3125 | trc2d(ji,jj,162) = trc2d(ji,jj,162) + (xphi * (fgmepn + fgmepd + fgmezmi + fgmed) * fthk) |
---|
3126 | !! mesozooplankton messy -> D |
---|
3127 | trc2d(ji,jj,163) = trc2d(ji,jj,163) + ((1. - xbetan) * finme * fthk) |
---|
3128 | !! mesozooplankton messy -> DIC |
---|
3129 | trc2d(ji,jj,164) = trc2d(ji,jj,164) + (xphi * ((xthetapn * fgmepn) + (xthetapd * fgmepd) + & |
---|
3130 | & (xthetazmi * fgmezmi) + fgmedc) * fthk) |
---|
3131 | !! mesozooplankton messy -> Dc |
---|
3132 | trc2d(ji,jj,165) = trc2d(ji,jj,165) + ((1. - xbetac) * ficme * fthk) |
---|
3133 | !! mesozooplankton excretion |
---|
3134 | trc2d(ji,jj,166) = trc2d(ji,jj,166) + (fmeexcr * fthk) |
---|
3135 | !! mesozooplankton respiration |
---|
3136 | trc2d(ji,jj,167) = trc2d(ji,jj,167) + (fmeresp * fthk) |
---|
3137 | !! mesozooplankton growth |
---|
3138 | trc2d(ji,jj,168) = trc2d(ji,jj,168) + (fmegrow * fthk) |
---|
3139 | !! ---------------------------------------------------------------------- |
---|
3140 | !! miscellaneous |
---|
3141 | trc2d(ji,jj,169) = trc2d(ji,jj,169) + (fddc * fthk) !! detrital C remineralisation |
---|
3142 | trc2d(ji,jj,170) = trc2d(ji,jj,170) + (fgmidc * fthk) !! microzoo grazing on detrital carbon |
---|
3143 | trc2d(ji,jj,171) = trc2d(ji,jj,171) + (fgmedc * fthk) !! mesozoo grazing on detrital carbon |
---|
3144 | !! |
---|
3145 | !! ---------------------------------------------------------------------- |
---|
3146 | !! |
---|
3147 | !! AXY (23/10/14): extract primary production related surface fields to |
---|
3148 | !! deal with diel cycle issues; hijacking BASIN 150m |
---|
3149 | !! diagnostics to do so (see commented out diagnostics |
---|
3150 | !! below this section) |
---|
3151 | !! |
---|
3152 | !! extract fields at surface |
---|
3153 | if (jk .eq. 1) then |
---|
3154 | trc2d(ji,jj,172) = zchn !! Pn chlorophyll |
---|
3155 | trc2d(ji,jj,173) = zphn !! Pn biomass |
---|
3156 | trc2d(ji,jj,174) = fjln !! Pn J-term |
---|
3157 | trc2d(ji,jj,175) = (fprn * zphn) !! Pn PP |
---|
3158 | trc2d(ji,jj,176) = zchd !! Pd chlorophyll |
---|
3159 | trc2d(ji,jj,177) = zphd !! Pd biomass |
---|
3160 | trc2d(ji,jj,178) = fjld !! Pd J-term |
---|
3161 | trc2d(ji,jj,179) = xpar(ji,jj,jk) !! Pd PP |
---|
3162 | trc2d(ji,jj,180) = loc_T !! local temperature |
---|
3163 | endif |
---|
3164 | !! |
---|
3165 | !! extract fields at 50m (actually 44-50m) |
---|
3166 | if (jk .eq. 18) then |
---|
3167 | trc2d(ji,jj,181) = zchn !! Pn chlorophyll |
---|
3168 | trc2d(ji,jj,182) = zphn !! Pn biomass |
---|
3169 | trc2d(ji,jj,183) = fjln !! Pn J-term |
---|
3170 | trc2d(ji,jj,184) = (fprn * zphn) !! Pn PP |
---|
3171 | trc2d(ji,jj,185) = zchd !! Pd chlorophyll |
---|
3172 | trc2d(ji,jj,186) = zphd !! Pd biomass |
---|
3173 | trc2d(ji,jj,187) = fjld !! Pd J-term |
---|
3174 | trc2d(ji,jj,188) = xpar(ji,jj,jk) !! Pd PP |
---|
3175 | trc2d(ji,jj,189) = loc_T !! local temperature |
---|
3176 | endif |
---|
3177 | !! |
---|
3178 | !! extract fields at 100m |
---|
3179 | if (jk .eq. i0100) then |
---|
3180 | trc2d(ji,jj,190) = zchn !! Pn chlorophyll |
---|
3181 | trc2d(ji,jj,191) = zphn !! Pn biomass |
---|
3182 | trc2d(ji,jj,192) = fjln !! Pn J-term |
---|
3183 | trc2d(ji,jj,193) = (fprn * zphn) !! Pn PP |
---|
3184 | trc2d(ji,jj,194) = zchd !! Pd chlorophyll |
---|
3185 | trc2d(ji,jj,195) = zphd !! Pd biomass |
---|
3186 | trc2d(ji,jj,196) = fjld !! Pd J-term |
---|
3187 | trc2d(ji,jj,197) = xpar(ji,jj,jk) !! Pd PP |
---|
3188 | trc2d(ji,jj,198) = loc_T !! local temperature |
---|
3189 | endif |
---|
3190 | !! extract relevant BASIN fields at 150m |
---|
3191 | if (jk .eq. i0150) then |
---|
3192 | !! trc2d(ji,jj,172) = trc2d(ji,jj,4) !! Pn PP |
---|
3193 | !! trc2d(ji,jj,173) = trc2d(ji,jj,151) !! Pn linear loss |
---|
3194 | !! trc2d(ji,jj,174) = trc2d(ji,jj,5) !! Pn non-linear loss |
---|
3195 | !! trc2d(ji,jj,175) = trc2d(ji,jj,11) !! Pn grazing to Zmi |
---|
3196 | !! trc2d(ji,jj,176) = trc2d(ji,jj,14) !! Pn grazing to Zme |
---|
3197 | !! trc2d(ji,jj,177) = trc2d(ji,jj,6) !! Pd PP |
---|
3198 | !! trc2d(ji,jj,178) = trc2d(ji,jj,152) !! Pd linear loss |
---|
3199 | !! trc2d(ji,jj,179) = trc2d(ji,jj,7) !! Pd non-linear loss |
---|
3200 | !! trc2d(ji,jj,180) = trc2d(ji,jj,15) !! Pd grazing to Zme |
---|
3201 | !! trc2d(ji,jj,181) = trc2d(ji,jj,12) !! Zmi grazing on D |
---|
3202 | !! trc2d(ji,jj,182) = trc2d(ji,jj,170) !! Zmi grazing on Dc |
---|
3203 | !! trc2d(ji,jj,183) = trc2d(ji,jj,155) !! Zmi messy feeding loss to N |
---|
3204 | !! trc2d(ji,jj,184) = trc2d(ji,jj,156) !! Zmi messy feeding loss to D |
---|
3205 | !! trc2d(ji,jj,185) = trc2d(ji,jj,157) !! Zmi messy feeding loss to DIC |
---|
3206 | !! trc2d(ji,jj,186) = trc2d(ji,jj,158) !! Zmi messy feeding loss to Dc |
---|
3207 | !! trc2d(ji,jj,187) = trc2d(ji,jj,159) !! Zmi excretion |
---|
3208 | !! trc2d(ji,jj,188) = trc2d(ji,jj,160) !! Zmi respiration |
---|
3209 | !! trc2d(ji,jj,189) = trc2d(ji,jj,161) !! Zmi growth |
---|
3210 | !! trc2d(ji,jj,190) = trc2d(ji,jj,153) !! Zmi linear loss |
---|
3211 | !! trc2d(ji,jj,191) = trc2d(ji,jj,13) !! Zmi non-linear loss |
---|
3212 | !! trc2d(ji,jj,192) = trc2d(ji,jj,16) !! Zmi grazing to Zme |
---|
3213 | !! trc2d(ji,jj,193) = trc2d(ji,jj,17) !! Zme grazing on D |
---|
3214 | !! trc2d(ji,jj,194) = trc2d(ji,jj,171) !! Zme grazing on Dc |
---|
3215 | !! trc2d(ji,jj,195) = trc2d(ji,jj,162) !! Zme messy feeding loss to N |
---|
3216 | !! trc2d(ji,jj,196) = trc2d(ji,jj,163) !! Zme messy feeding loss to D |
---|
3217 | !! trc2d(ji,jj,197) = trc2d(ji,jj,164) !! Zme messy feeding loss to DIC |
---|
3218 | !! trc2d(ji,jj,198) = trc2d(ji,jj,165) !! Zme messy feeding loss to Dc |
---|
3219 | trc2d(ji,jj,199) = trc2d(ji,jj,166) !! Zme excretion |
---|
3220 | trc2d(ji,jj,200) = trc2d(ji,jj,167) !! Zme respiration |
---|
3221 | trc2d(ji,jj,201) = trc2d(ji,jj,168) !! Zme growth |
---|
3222 | trc2d(ji,jj,202) = trc2d(ji,jj,154) !! Zme linear loss |
---|
3223 | trc2d(ji,jj,203) = trc2d(ji,jj,18) !! Zme non-linear loss |
---|
3224 | trc2d(ji,jj,204) = trc2d(ji,jj,20) !! Slow detritus production, N |
---|
3225 | trc2d(ji,jj,205) = trc2d(ji,jj,21) !! Slow detritus remineralisation, N |
---|
3226 | trc2d(ji,jj,206) = trc2d(ji,jj,141) !! Slow detritus production, C |
---|
3227 | trc2d(ji,jj,207) = trc2d(ji,jj,169) !! Slow detritus remineralisation, C |
---|
3228 | trc2d(ji,jj,208) = trc2d(ji,jj,43) !! Fast detritus production, N |
---|
3229 | trc2d(ji,jj,209) = trc2d(ji,jj,21) !! Fast detritus remineralisation, N |
---|
3230 | trc2d(ji,jj,210) = trc2d(ji,jj,64) !! Fast detritus production, C |
---|
3231 | trc2d(ji,jj,211) = trc2d(ji,jj,67) !! Fast detritus remineralisation, C |
---|
3232 | trc2d(ji,jj,212) = trc2d(ji,jj,150) !! Community respiration |
---|
3233 | trc2d(ji,jj,213) = fslownflux !! Slow detritus N flux at 150 m |
---|
3234 | trc2d(ji,jj,214) = fslowcflux !! Slow detritus C flux at 150 m |
---|
3235 | trc2d(ji,jj,215) = ffastn(ji,jj) !! Fast detritus N flux at 150 m |
---|
3236 | trc2d(ji,jj,216) = ffastc(ji,jj) !! Fast detritus C flux at 150 m |
---|
3237 | endif |
---|
3238 | !! |
---|
3239 | !! Jpalm (11-08-2014) |
---|
3240 | !! Add UKESM1 diagnoatics |
---|
3241 | !!^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
---|
3242 | if ((jk .eq. 1) .and.( jdms.eq.1)) then |
---|
3243 | trc2d(ji,jj,221) = dms_surf !! DMS surface concentration |
---|
3244 | !! AXY (13/03/15): add in other DMS estimates |
---|
3245 | trc2d(ji,jj,222) = dms_andr !! DMS surface concentration |
---|
3246 | trc2d(ji,jj,223) = dms_simo !! DMS surface concentration |
---|
3247 | trc2d(ji,jj,224) = dms_aran !! DMS surface concentration |
---|
3248 | trc2d(ji,jj,225) = dms_hall !! DMS surface concentration |
---|
3249 | endif |
---|
3250 | # endif |
---|
3251 | !! other possible future diagnostics include: |
---|
3252 | !! - integrated tracer values (esp. biological) |
---|
3253 | !! - mixed layer tracer values |
---|
3254 | !! - sub-surface chlorophyll maxima (plus depth) |
---|
3255 | !! - different mixed layer depth criteria (T, sigma, var. sigma) |
---|
3256 | |
---|
3257 | !!---------------------------------------------------------------------- |
---|
3258 | !! Prepare 3D diagnostics |
---|
3259 | !!---------------------------------------------------------------------- |
---|
3260 | !! |
---|
3261 | trc3d(ji,jj,jk,1) = ((fprn + fprd) * zphn) !! primary production |
---|
3262 | trc3d(ji,jj,jk,2) = fslownflux + ffastn(ji,jj) !! detrital flux |
---|
3263 | trc3d(ji,jj,jk,3) = fregen + (freminn * fthk) !! remineralisation |
---|
3264 | # if defined key_roam |
---|
3265 | trc3d(ji,jj,jk,4) = f3_pH(ji,jj,jk) !! pH |
---|
3266 | trc3d(ji,jj,jk,5) = f3_omcal(ji,jj,jk) !! omega calcite |
---|
3267 | # else |
---|
3268 | trc3d(ji,jj,jk,4) = ffastsi(ji,jj) !! fast Si flux |
---|
3269 | # endif |
---|
3270 | ENDIF ! end of ln_diatrc option |
---|
3271 | !! CLOSE wet point IF..THEN loop |
---|
3272 | endif |
---|
3273 | !! CLOSE horizontal loops |
---|
3274 | END DO |
---|
3275 | END DO |
---|
3276 | !! CLOSE vertical loop |
---|
3277 | END DO |
---|
3278 | |
---|
3279 | !!---------------------------------------------------------------------- |
---|
3280 | !! Process benthic in/out fluxes |
---|
3281 | !! These can be handled outside of the 3D calculations since the |
---|
3282 | !! benthic pools (and fluxes) are 2D in nature; this code is |
---|
3283 | !! (shamelessly) borrowed from corresponding code in the LOBSTER |
---|
3284 | !! model |
---|
3285 | !!---------------------------------------------------------------------- |
---|
3286 | !! |
---|
3287 | !! IF(lwp) WRITE(numout,*) 'AXY: rdt = ', rdt |
---|
3288 | if (jorgben.eq.1) then |
---|
3289 | za_sed_n(:,:) = zn_sed_n(:,:) + & |
---|
3290 | & ( f_sbenin_n(:,:) + f_fbenin_n(:,:) - f_benout_n(:,:) ) * (rdt / 86400.) |
---|
3291 | zn_sed_n(:,:) = za_sed_n(:,:) |
---|
3292 | !! |
---|
3293 | za_sed_fe(:,:) = zn_sed_fe(:,:) + & |
---|
3294 | & ( f_sbenin_fe(:,:) + f_fbenin_fe(:,:) - f_benout_fe(:,:) ) * (rdt / 86400.) |
---|
3295 | zn_sed_fe(:,:) = za_sed_fe(:,:) |
---|
3296 | !! |
---|
3297 | za_sed_c(:,:) = zn_sed_c(:,:) + & |
---|
3298 | & ( f_sbenin_c(:,:) + f_fbenin_c(:,:) - f_benout_c(:,:) ) * (rdt / 86400.) |
---|
3299 | zn_sed_c(:,:) = za_sed_c(:,:) |
---|
3300 | endif |
---|
3301 | if (jinorgben.eq.1) then |
---|
3302 | za_sed_si(:,:) = zn_sed_si(:,:) + & |
---|
3303 | & ( f_fbenin_si(:,:) - f_benout_si(:,:) ) * (rdt / 86400.) |
---|
3304 | zn_sed_si(:,:) = za_sed_si(:,:) |
---|
3305 | !! |
---|
3306 | za_sed_ca(:,:) = zn_sed_ca(:,:) + & |
---|
3307 | & ( f_fbenin_ca(:,:) - f_benout_ca(:,:) ) * (rdt / 86400.) |
---|
3308 | zn_sed_ca(:,:) = za_sed_ca(:,:) |
---|
3309 | endif |
---|
3310 | DO jj = 2,jpjm1 |
---|
3311 | DO ji = 2,jpim1 |
---|
3312 | trc2d(ji,jj,131) = za_sed_n(ji,jj) |
---|
3313 | trc2d(ji,jj,132) = za_sed_fe(ji,jj) |
---|
3314 | trc2d(ji,jj,133) = za_sed_c(ji,jj) |
---|
3315 | trc2d(ji,jj,134) = za_sed_si(ji,jj) |
---|
3316 | trc2d(ji,jj,135) = za_sed_ca(ji,jj) |
---|
3317 | ENDDO |
---|
3318 | ENDDO |
---|
3319 | |
---|
3320 | if (ibenthic.eq.2) then |
---|
3321 | !! The code below (in this if ... then ... endif loop) is |
---|
3322 | !! effectively commented out because it does not work as |
---|
3323 | !! anticipated; it can be deleted at a later date |
---|
3324 | if (jorgben.eq.1) then |
---|
3325 | za_sed_n(:,:) = ( f_sbenin_n(:,:) + f_fbenin_n(:,:) - f_benout_n(:,:) ) * rdt |
---|
3326 | za_sed_fe(:,:) = ( f_sbenin_fe(:,:) + f_fbenin_fe(:,:) - f_benout_fe(:,:) ) * rdt |
---|
3327 | za_sed_c(:,:) = ( f_sbenin_c(:,:) + f_fbenin_c(:,:) - f_benout_c(:,:) ) * rdt |
---|
3328 | endif |
---|
3329 | if (jinorgben.eq.1) then |
---|
3330 | za_sed_si(:,:) = ( f_fbenin_si(:,:) - f_benout_si(:,:) ) * rdt |
---|
3331 | za_sed_ca(:,:) = ( f_fbenin_ca(:,:) - f_benout_ca(:,:) ) * rdt |
---|
3332 | endif |
---|
3333 | !! |
---|
3334 | !! Leap-frog scheme - only in explicit case, otherwise the time stepping |
---|
3335 | !! is already being done in trczdf |
---|
3336 | !! IF( l_trczdf_exp .AND. (ln_trcadv_cen2 .OR. ln_trcadv_tvd) ) THEN |
---|
3337 | !! zfact = 2. * rdttra(jk) * FLOAT( ndttrc ) |
---|
3338 | !! IF( neuler == 0 .AND. kt == nittrc000 ) zfact = rdttra(jk) * FLOAT(ndttrc) |
---|
3339 | !! if (jorgben.eq.1) then |
---|
3340 | !! za_sed_n(:,:) = zb_sed_n(:,:) + ( zfact * za_sed_n(:,:) ) |
---|
3341 | !! za_sed_fe(:,:) = zb_sed_fe(:,:) + ( zfact * za_sed_fe(:,:) ) |
---|
3342 | !! za_sed_c(:,:) = zb_sed_c(:,:) + ( zfact * za_sed_c(:,:) ) |
---|
3343 | !! endif |
---|
3344 | !! if (jinorgben.eq.1) then |
---|
3345 | !! za_sed_si(:,:) = zb_sed_si(:,:) + ( zfact * za_sed_si(:,:) ) |
---|
3346 | !! za_sed_ca(:,:) = zb_sed_ca(:,:) + ( zfact * za_sed_ca(:,:) ) |
---|
3347 | !! endif |
---|
3348 | !! ENDIF |
---|
3349 | !! |
---|
3350 | !! Time filter and swap of arrays |
---|
3351 | IF( ln_trcadv_cen2 .OR. ln_trcadv_tvd ) THEN ! centred or tvd scheme |
---|
3352 | IF( neuler == 0 .AND. kt == nittrc000 ) THEN |
---|
3353 | if (jorgben.eq.1) then |
---|
3354 | zb_sed_n(:,:) = zn_sed_n(:,:) |
---|
3355 | zn_sed_n(:,:) = za_sed_n(:,:) |
---|
3356 | za_sed_n(:,:) = 0.0 |
---|
3357 | !! |
---|
3358 | zb_sed_fe(:,:) = zn_sed_fe(:,:) |
---|
3359 | zn_sed_fe(:,:) = za_sed_fe(:,:) |
---|
3360 | za_sed_fe(:,:) = 0.0 |
---|
3361 | !! |
---|
3362 | zb_sed_c(:,:) = zn_sed_c(:,:) |
---|
3363 | zn_sed_c(:,:) = za_sed_c(:,:) |
---|
3364 | za_sed_c(:,:) = 0.0 |
---|
3365 | endif |
---|
3366 | if (jinorgben.eq.1) then |
---|
3367 | zb_sed_si(:,:) = zn_sed_si(:,:) |
---|
3368 | zn_sed_si(:,:) = za_sed_si(:,:) |
---|
3369 | za_sed_si(:,:) = 0.0 |
---|
3370 | !! |
---|
3371 | zb_sed_ca(:,:) = zn_sed_ca(:,:) |
---|
3372 | zn_sed_ca(:,:) = za_sed_ca(:,:) |
---|
3373 | za_sed_ca(:,:) = 0.0 |
---|
3374 | endif |
---|
3375 | ELSE |
---|
3376 | if (jorgben.eq.1) then |
---|
3377 | zb_sed_n(:,:) = (atfp * ( zb_sed_n(:,:) + za_sed_n(:,:) )) + (atfp1 * zn_sed_n(:,:) ) |
---|
3378 | zn_sed_n(:,:) = za_sed_n(:,:) |
---|
3379 | za_sed_n(:,:) = 0.0 |
---|
3380 | !! |
---|
3381 | zb_sed_fe(:,:) = (atfp * ( zb_sed_fe(:,:) + za_sed_fe(:,:) )) + (atfp1 * zn_sed_fe(:,:)) |
---|
3382 | zn_sed_fe(:,:) = za_sed_fe(:,:) |
---|
3383 | za_sed_fe(:,:) = 0.0 |
---|
3384 | !! |
---|
3385 | zb_sed_c(:,:) = (atfp * ( zb_sed_c(:,:) + za_sed_c(:,:) )) + (atfp1 * zn_sed_c(:,:) ) |
---|
3386 | zn_sed_c(:,:) = za_sed_c(:,:) |
---|
3387 | za_sed_c(:,:) = 0.0 |
---|
3388 | endif |
---|
3389 | if (jinorgben.eq.1) then |
---|
3390 | zb_sed_si(:,:) = (atfp * ( zb_sed_si(:,:) + za_sed_si(:,:) )) + (atfp1 * zn_sed_si(:,:)) |
---|
3391 | zn_sed_si(:,:) = za_sed_si(:,:) |
---|
3392 | za_sed_si(:,:) = 0.0 |
---|
3393 | !! |
---|
3394 | zb_sed_ca(:,:) = (atfp * ( zb_sed_ca(:,:) + za_sed_ca(:,:) )) + (atfp1 * zn_sed_ca(:,:)) |
---|
3395 | zn_sed_ca(:,:) = za_sed_ca(:,:) |
---|
3396 | za_sed_ca(:,:) = 0.0 |
---|
3397 | endif |
---|
3398 | ENDIF |
---|
3399 | ELSE ! case of smolar scheme or muscl |
---|
3400 | if (jorgben.eq.1) then |
---|
3401 | zb_sed_n(:,:) = za_sed_n(:,:) |
---|
3402 | zn_sed_n(:,:) = za_sed_n(:,:) |
---|
3403 | za_sed_n(:,:) = 0.0 |
---|
3404 | !! |
---|
3405 | zb_sed_fe(:,:) = za_sed_fe(:,:) |
---|
3406 | zn_sed_fe(:,:) = za_sed_fe(:,:) |
---|
3407 | za_sed_fe(:,:) = 0.0 |
---|
3408 | !! |
---|
3409 | zb_sed_c(:,:) = za_sed_c(:,:) |
---|
3410 | zn_sed_c(:,:) = za_sed_c(:,:) |
---|
3411 | za_sed_c(:,:) = 0.0 |
---|
3412 | endif |
---|
3413 | if (jinorgben.eq.1) then |
---|
3414 | zb_sed_si(:,:) = za_sed_si(:,:) |
---|
3415 | zn_sed_si(:,:) = za_sed_si(:,:) |
---|
3416 | za_sed_si(:,:) = 0.0 |
---|
3417 | !! |
---|
3418 | zb_sed_ca(:,:) = za_sed_ca(:,:) |
---|
3419 | zn_sed_ca(:,:) = za_sed_ca(:,:) |
---|
3420 | za_sed_ca(:,:) = 0.0 |
---|
3421 | endif |
---|
3422 | ENDIF |
---|
3423 | endif |
---|
3424 | |
---|
3425 | IF( ln_diatrc ) THEN |
---|
3426 | !!---------------------------------------------------------------------- |
---|
3427 | !! Output several accumulated diagnostics |
---|
3428 | !! - biomass-average phytoplankton limitation terms |
---|
3429 | !! - integrated tendency terms |
---|
3430 | !!---------------------------------------------------------------------- |
---|
3431 | !! |
---|
3432 | DO jj = 2,jpjm1 |
---|
3433 | DO ji = 2,jpim1 |
---|
3434 | !! non-diatom phytoplankton limitations |
---|
3435 | trc2d(ji,jj,25) = trc2d(ji,jj,25) / MAX(ftot_pn(ji,jj), rsmall) |
---|
3436 | trc2d(ji,jj,26) = trc2d(ji,jj,26) / MAX(ftot_pn(ji,jj), rsmall) |
---|
3437 | trc2d(ji,jj,27) = trc2d(ji,jj,27) / MAX(ftot_pn(ji,jj), rsmall) |
---|
3438 | !! diatom phytoplankton limitations |
---|
3439 | trc2d(ji,jj,28) = trc2d(ji,jj,28) / MAX(ftot_pd(ji,jj), rsmall) |
---|
3440 | trc2d(ji,jj,29) = trc2d(ji,jj,29) / MAX(ftot_pd(ji,jj), rsmall) |
---|
3441 | trc2d(ji,jj,30) = trc2d(ji,jj,30) / MAX(ftot_pd(ji,jj), rsmall) |
---|
3442 | trc2d(ji,jj,31) = trc2d(ji,jj,31) / MAX(ftot_pd(ji,jj), rsmall) |
---|
3443 | trc2d(ji,jj,32) = trc2d(ji,jj,32) / MAX(ftot_pd(ji,jj), rsmall) |
---|
3444 | !! tendency terms |
---|
3445 | trc2d(ji,jj,76) = fflx_n(ji,jj) |
---|
3446 | trc2d(ji,jj,77) = fflx_si(ji,jj) |
---|
3447 | trc2d(ji,jj,78) = fflx_fe(ji,jj) |
---|
3448 | !! integrated biomass |
---|
3449 | trc2d(ji,jj,79) = ftot_pn(ji,jj) !! integrated non-diatom phytoplankton |
---|
3450 | trc2d(ji,jj,80) = ftot_pd(ji,jj) !! integrated diatom phytoplankton |
---|
3451 | trc2d(ji,jj,217) = ftot_zmi(ji,jj) !! Integrated microzooplankton |
---|
3452 | trc2d(ji,jj,218) = ftot_zme(ji,jj) !! Integrated mesozooplankton |
---|
3453 | trc2d(ji,jj,219) = ftot_det(ji,jj) !! Integrated slow detritus, nitrogen |
---|
3454 | trc2d(ji,jj,220) = ftot_dtc(ji,jj) !! Integrated slow detritus, carbon |
---|
3455 | # if defined key_roam |
---|
3456 | !! the balance of nitrogen production/consumption |
---|
3457 | trc2d(ji,jj,111) = fnit_prod(ji,jj) !! integrated nitrogen production |
---|
3458 | trc2d(ji,jj,112) = fnit_cons(ji,jj) !! integrated nitrogen consumption |
---|
3459 | !! the balance of carbon production/consumption |
---|
3460 | trc2d(ji,jj,113) = fcar_prod(ji,jj) !! integrated carbon production |
---|
3461 | trc2d(ji,jj,114) = fcar_cons(ji,jj) !! integrated carbon consumption |
---|
3462 | !! the balance of oxygen production/consumption |
---|
3463 | trc2d(ji,jj,115) = foxy_prod(ji,jj) !! integrated oxygen production |
---|
3464 | trc2d(ji,jj,116) = foxy_cons(ji,jj) !! integrated oxygen consumption |
---|
3465 | trc2d(ji,jj,117) = foxy_anox(ji,jj) !! integrated unrealised oxygen consumption |
---|
3466 | # endif |
---|
3467 | END DO |
---|
3468 | END DO |
---|
3469 | |
---|
3470 | # if defined key_roam |
---|
3471 | # if defined key_axy_nancheck |
---|
3472 | !!---------------------------------------------------------------------- |
---|
3473 | !! Check for NaNs in diagnostic outputs |
---|
3474 | !!---------------------------------------------------------------------- |
---|
3475 | !! |
---|
3476 | !! 2D diagnostics |
---|
3477 | DO jn = 1,150 |
---|
3478 | fq0 = SUM(trc2d(:,:,jn)) |
---|
3479 | !! AXY (30/01/14): "isnan" problem on HECTOR |
---|
3480 | !! if (fq0 /= fq0 ) then |
---|
3481 | if ( ieee_is_nan( fq0 ) ) then |
---|
3482 | !! there's a NaN here |
---|
3483 | if (lwp) write(numout,*) 'NAN detected in 2D diagnostic field', jn, 'at time', kt, 'at position:' |
---|
3484 | DO jj = 1,jpj |
---|
3485 | DO ji = 1,jpi |
---|
3486 | if ( ieee_is_nan( trc2d(ji,jj,jn) ) ) then |
---|
3487 | if (lwp) write (numout,'(a,3i6)') 'NAN-CHECK', & |
---|
3488 | & ji, jj, jn |
---|
3489 | endif |
---|
3490 | enddo |
---|
3491 | enddo |
---|
3492 | CALL ctl_stop( 'trcbio_medusa, NAN in 2D diagnostic field' ) |
---|
3493 | endif |
---|
3494 | ENDDO |
---|
3495 | !! |
---|
3496 | !! 3D diagnostics |
---|
3497 | DO jn = 1,5 |
---|
3498 | fq0 = SUM(trc3d(:,:,:,jn)) |
---|
3499 | !! AXY (30/01/14): "isnan" problem on HECTOR |
---|
3500 | !! if (fq0 /= fq0 ) then |
---|
3501 | if ( ieee_is_nan( fq0 ) ) then |
---|
3502 | !! there's a NaN here |
---|
3503 | if (lwp) write(numout,*) 'NAN detected in 3D diagnostic field', jn, 'at time', kt, 'at position:' |
---|
3504 | DO jk = 1,jpk |
---|
3505 | DO jj = 1,jpj |
---|
3506 | DO ji = 1,jpi |
---|
3507 | if ( ieee_is_nan( trc3d(ji,jj,jk,jn) ) ) then |
---|
3508 | if (lwp) write (numout,'(a,4i6)') 'NAN-CHECK', & |
---|
3509 | & ji, jj, jk, jn |
---|
3510 | endif |
---|
3511 | enddo |
---|
3512 | enddo |
---|
3513 | enddo |
---|
3514 | CALL ctl_stop( 'trcbio_medusa, NAN in 3D diagnostic field' ) |
---|
3515 | endif |
---|
3516 | ENDDO |
---|
3517 | CALL flush(numout) |
---|
3518 | # endif |
---|
3519 | # endif |
---|
3520 | |
---|
3521 | !!---------------------------------------------------------------------- |
---|
3522 | !! Don't know what this does; belongs to someone else ... |
---|
3523 | !!---------------------------------------------------------------------- |
---|
3524 | !! |
---|
3525 | !! Lateral boundary conditions on trc2d |
---|
3526 | DO jn=1,jp_medusa_2d |
---|
3527 | CALL lbc_lnk(trc2d(:,:,jn),'T',1. ) |
---|
3528 | END DO |
---|
3529 | |
---|
3530 | !! Lateral boundary conditions on trc3d |
---|
3531 | DO jn=1,jp_medusa_3d |
---|
3532 | CALL lbc_lnk(trc3d(:,:,1,jn),'T',1. ) |
---|
3533 | END DO |
---|
3534 | |
---|
3535 | # if defined key_axy_nodiag |
---|
3536 | !!---------------------------------------------------------------------- |
---|
3537 | !! Blank diagnostics as a NaN-trap |
---|
3538 | !!---------------------------------------------------------------------- |
---|
3539 | !! |
---|
3540 | !! blank 2D diagnostic array |
---|
3541 | trc2d(:,:,:) = 0.e0 |
---|
3542 | !! |
---|
3543 | !! blank 3D diagnostic array |
---|
3544 | trc3d(:,:,:,:) = 0.e0 |
---|
3545 | # endif |
---|
3546 | |
---|
3547 | # if defined key_iomput |
---|
3548 | !!---------------------------------------------------------------------- |
---|
3549 | !! Add in XML diagnostics stuff |
---|
3550 | !!---------------------------------------------------------------------- |
---|
3551 | !! |
---|
3552 | !! ** 2D diagnostics |
---|
3553 | DO jn=1,jp_medusa_2d |
---|
3554 | CALL iom_put(TRIM(ctrc2d(jn)), trc2d(:,:,jn)) |
---|
3555 | END DO |
---|
3556 | !! AXY (17/02/14): don't think I need this if I modify the above for all diagnostics |
---|
3557 | !! # if defined key_roam |
---|
3558 | !! DO jn=91,jp_medusa_2d |
---|
3559 | !! CALL iom_put(TRIM(ctrc2d(jn)), trc2d(:,:,jn)) |
---|
3560 | !! END DO |
---|
3561 | !! # endif |
---|
3562 | !! |
---|
3563 | !! ** 3D diagnostics |
---|
3564 | DO jn=1,jp_medusa_3d |
---|
3565 | CALL iom_put(TRIM(ctrc3d(jn)), trc3d(:,:,:,jn)) |
---|
3566 | END DO |
---|
3567 | !! AXY (17/02/14): don't think I need this if I modify the above for all diagnostics |
---|
3568 | !! # if defined key_roam |
---|
3569 | !! CALL iom_put(TRIM(ctrc3d(5)), trc3d(:,:,:,5)) |
---|
3570 | !! # endif |
---|
3571 | # endif |
---|
3572 | ENDIF ! end of ln_diatrc option |
---|
3573 | |
---|
3574 | # if defined key_trc_diabio |
---|
3575 | !! Lateral boundary conditions on trcbio |
---|
3576 | DO jn=1,jp_medusa_trd |
---|
3577 | CALL lbc_lnk(trbio(:,:,1,jn),'T',1. ) |
---|
3578 | END DO |
---|
3579 | # endif |
---|
3580 | |
---|
3581 | # if defined key_debug_medusa |
---|
3582 | IF(lwp) WRITE(numout,*) ' MEDUSA exiting trc_bio_medusa at kt =', kt |
---|
3583 | CALL flush(numout) |
---|
3584 | # endif |
---|
3585 | |
---|
3586 | END SUBROUTINE trc_bio_medusa |
---|
3587 | |
---|
3588 | #else |
---|
3589 | !!====================================================================== |
---|
3590 | !! Dummy module : No MEDUSA bio-model |
---|
3591 | !!====================================================================== |
---|
3592 | CONTAINS |
---|
3593 | SUBROUTINE trc_bio_medusa( kt ) ! Empty routine |
---|
3594 | INTEGER, INTENT( in ) :: kt |
---|
3595 | WRITE(*,*) 'trc_bio_medusa: You should not have seen this print! error?', kt |
---|
3596 | END SUBROUTINE trc_bio_medusa |
---|
3597 | #endif |
---|
3598 | |
---|
3599 | !!====================================================================== |
---|
3600 | END MODULE trcbio_medusa |
---|