[8586] | 1 | MODULE icethd_dh |
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| 2 | !!====================================================================== |
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| 3 | !! *** MODULE icethd_dh *** |
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| 4 | !! seaice : thermodynamic growth and melt |
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| 5 | !!====================================================================== |
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[9604] | 6 | !! History : ! 2003-05 (M. Vancoppenolle) Original code in 1D |
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| 7 | !! ! 2005-06 (M. Vancoppenolle) 3D version |
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| 8 | !! 4.0 ! 2018 (many people) SI3 [aka Sea Ice cube] |
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[8586] | 9 | !!---------------------------------------------------------------------- |
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[9570] | 10 | #if defined key_si3 |
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[8586] | 11 | !!---------------------------------------------------------------------- |
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[9570] | 12 | !! 'key_si3' SI3 sea-ice model |
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[8586] | 13 | !!---------------------------------------------------------------------- |
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| 14 | !! ice_thd_dh : vertical sea-ice growth and melt |
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| 15 | !! ice_thd_snwblow : distribute snow fall between ice and ocean |
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| 16 | !!---------------------------------------------------------------------- |
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| 17 | USE dom_oce ! ocean space and time domain |
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| 18 | USE phycst ! physical constants |
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| 19 | USE ice ! sea-ice: variables |
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| 20 | USE ice1D ! sea-ice: thermodynamics variables |
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| 21 | USE icethd_sal ! sea-ice: salinity profiles |
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| 22 | ! |
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| 23 | USE in_out_manager ! I/O manager |
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| 24 | USE lib_mpp ! MPP library |
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| 25 | USE lib_fortran ! fortran utilities (glob_sum + no signed zero) |
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| 26 | |
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| 27 | IMPLICIT NONE |
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| 28 | PRIVATE |
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| 29 | |
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| 30 | PUBLIC ice_thd_dh ! called by ice_thd |
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[9274] | 31 | PUBLIC ice_thd_snwblow ! called in sbcblk/sbccpl and here |
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[8586] | 32 | |
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| 33 | INTERFACE ice_thd_snwblow |
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| 34 | MODULE PROCEDURE ice_thd_snwblow_1d, ice_thd_snwblow_2d |
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| 35 | END INTERFACE |
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| 36 | |
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| 37 | !!---------------------------------------------------------------------- |
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[9598] | 38 | !! NEMO/ICE 4.0 , NEMO Consortium (2018) |
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[10069] | 39 | !! $Id$ |
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[10068] | 40 | !! Software governed by the CeCILL license (see ./LICENSE) |
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[8586] | 41 | !!---------------------------------------------------------------------- |
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| 42 | CONTAINS |
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| 43 | |
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| 44 | SUBROUTINE ice_thd_dh |
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| 45 | !!------------------------------------------------------------------ |
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| 46 | !! *** ROUTINE ice_thd_dh *** |
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| 47 | !! |
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[9274] | 48 | !! ** Purpose : compute ice and snow thickness changes due to growth/melting |
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[8586] | 49 | !! |
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| 50 | !! ** Method : Ice/Snow surface melting arises from imbalance in surface fluxes |
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[9274] | 51 | !! Bottom accretion/ablation arises from flux budget |
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| 52 | !! Snow thickness can increase by precipitation and decrease by sublimation |
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| 53 | !! If snow load excesses Archmiede limit, snow-ice is formed by |
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| 54 | !! the flooding of sea-water in the snow |
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[8586] | 55 | !! |
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[9274] | 56 | !! - Compute available flux of heat for surface ablation |
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| 57 | !! - Compute snow and sea ice enthalpies |
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| 58 | !! - Surface ablation and sublimation |
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| 59 | !! - Bottom accretion/ablation |
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| 60 | !! - Snow ice formation |
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[8586] | 61 | !! |
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| 62 | !! References : Bitz and Lipscomb, 1999, J. Geophys. Res. |
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| 63 | !! Fichefet T. and M. Maqueda 1997, J. Geophys. Res., 102(C6), 12609-12646 |
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| 64 | !! Vancoppenolle, Fichefet and Bitz, 2005, Geophys. Res. Let. |
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| 65 | !! Vancoppenolle et al.,2009, Ocean Modelling |
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| 66 | !!------------------------------------------------------------------ |
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| 67 | INTEGER :: ji, jk ! dummy loop indices |
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| 68 | INTEGER :: iter ! local integer |
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| 69 | |
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| 70 | REAL(wp) :: ztmelts ! local scalar |
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| 71 | REAL(wp) :: zdum |
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| 72 | REAL(wp) :: zfracs ! fractionation coefficient for bottom salt entrapment |
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| 73 | REAL(wp) :: zswi1 ! switch for computation of bottom salinity |
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| 74 | REAL(wp) :: zswi12 ! switch for computation of bottom salinity |
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| 75 | REAL(wp) :: zswi2 ! switch for computation of bottom salinity |
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| 76 | REAL(wp) :: zgrr ! bottom growth rate |
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| 77 | REAL(wp) :: zt_i_new ! bottom formation temperature |
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[9935] | 78 | REAL(wp) :: z1_rho ! 1/(rhos+rau0-rhoi) |
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[8586] | 79 | |
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| 80 | REAL(wp) :: zQm ! enthalpy exchanged with the ocean (J/m2), >0 towards the ocean |
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| 81 | REAL(wp) :: zEi ! specific enthalpy of sea ice (J/kg) |
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| 82 | REAL(wp) :: zEw ! specific enthalpy of exchanged water (J/kg) |
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| 83 | REAL(wp) :: zdE ! specific enthalpy difference (J/kg) |
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| 84 | REAL(wp) :: zfmdt ! exchange mass flux x time step (J/m2), >0 towards the ocean |
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| 85 | |
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| 86 | REAL(wp), DIMENSION(jpij) :: zqprec ! energy of fallen snow (J.m-3) |
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[9922] | 87 | REAL(wp), DIMENSION(jpij) :: zq_top ! heat for surface ablation (J.m-2) |
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| 88 | REAL(wp), DIMENSION(jpij) :: zq_bot ! heat for bottom ablation (J.m-2) |
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[8586] | 89 | REAL(wp), DIMENSION(jpij) :: zq_rema ! remaining heat at the end of the routine (J.m-2) |
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| 90 | REAL(wp), DIMENSION(jpij) :: zf_tt ! Heat budget to determine melting or freezing(W.m-2) |
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| 91 | REAL(wp), DIMENSION(jpij) :: zevap_rema ! remaining mass flux from sublimation (kg.m-2) |
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| 92 | |
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| 93 | REAL(wp), DIMENSION(jpij) :: zdh_s_mel ! snow melt |
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| 94 | REAL(wp), DIMENSION(jpij) :: zdh_s_pre ! snow precipitation |
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| 95 | REAL(wp), DIMENSION(jpij) :: zdh_s_sub ! snow sublimation |
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| 96 | |
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[9271] | 97 | REAL(wp), DIMENSION(jpij,nlay_s) :: zh_s ! snw layer thickness |
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| 98 | REAL(wp), DIMENSION(jpij,nlay_i) :: zh_i ! ice layer thickness |
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[8586] | 99 | REAL(wp), DIMENSION(jpij,nlay_i) :: zdeltah |
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| 100 | INTEGER , DIMENSION(jpij,nlay_i) :: icount ! number of layers vanished by melting |
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| 101 | |
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| 102 | REAL(wp), DIMENSION(jpij) :: zsnw ! distribution of snow after wind blowing |
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| 103 | |
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| 104 | REAL(wp) :: zswitch_sal |
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| 105 | |
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| 106 | INTEGER :: num_iter_max ! Heat conservation |
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| 107 | !!------------------------------------------------------------------ |
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| 108 | |
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| 109 | ! Discriminate between time varying salinity and constant |
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| 110 | SELECT CASE( nn_icesal ) ! varying salinity or not |
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| 111 | CASE( 1 , 3 ) ; zswitch_sal = 0._wp ! prescribed salinity profile |
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| 112 | CASE( 2 ) ; zswitch_sal = 1._wp ! varying salinity profile |
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| 113 | END SELECT |
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| 114 | |
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| 115 | ! initialize layer thicknesses and enthalpies |
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| 116 | h_i_old (1:npti,0:nlay_i+1) = 0._wp |
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| 117 | eh_i_old(1:npti,0:nlay_i+1) = 0._wp |
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| 118 | DO jk = 1, nlay_i |
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| 119 | DO ji = 1, npti |
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| 120 | h_i_old (ji,jk) = h_i_1d(ji) * r1_nlay_i |
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| 121 | eh_i_old(ji,jk) = e_i_1d(ji,jk) * h_i_old(ji,jk) |
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| 122 | END DO |
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| 123 | END DO |
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| 124 | ! |
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[9604] | 125 | ! ! ============================================== ! |
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| 126 | ! ! Available heat for surface and bottom ablation ! |
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| 127 | ! ! ============================================== ! |
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[8813] | 128 | ! |
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[10534] | 129 | IF( ln_cndflx .AND. .NOT.ln_cndemulate ) THEN |
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[8813] | 130 | ! |
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| 131 | DO ji = 1, npti |
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[9922] | 132 | zq_top(ji) = MAX( 0._wp, qml_ice_1d(ji) * rdt_ice ) |
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[8813] | 133 | END DO |
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| 134 | ! |
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[10534] | 135 | ELSE |
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[8813] | 136 | ! |
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| 137 | DO ji = 1, npti |
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[9916] | 138 | zdum = qns_ice_1d(ji) + qsr_ice_1d(ji) - qtr_ice_top_1d(ji) - qcn_ice_top_1d(ji) |
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[9274] | 139 | qml_ice_1d(ji) = zdum * MAX( 0._wp , SIGN( 1._wp, t_su_1d(ji) - rt0 ) ) |
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[9922] | 140 | zq_top(ji) = MAX( 0._wp, qml_ice_1d(ji) * rdt_ice ) |
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[8813] | 141 | END DO |
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| 142 | ! |
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[10534] | 143 | ENDIF |
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[8813] | 144 | ! |
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[8586] | 145 | DO ji = 1, npti |
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[9916] | 146 | zf_tt(ji) = qcn_ice_bot_1d(ji) + qsb_ice_bot_1d(ji) + fhld_1d(ji) |
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[9922] | 147 | zq_bot(ji) = MAX( 0._wp, zf_tt(ji) * rdt_ice ) |
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[8586] | 148 | END DO |
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| 149 | |
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[9274] | 150 | ! Ice and snow layer thicknesses |
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| 151 | !------------------------------- |
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[9271] | 152 | DO jk = 1, nlay_i |
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| 153 | DO ji = 1, npti |
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| 154 | zh_i(ji,jk) = h_i_1d(ji) * r1_nlay_i |
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| 155 | END DO |
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| 156 | END DO |
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| 157 | |
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| 158 | DO jk = 1, nlay_s |
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| 159 | DO ji = 1, npti |
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| 160 | zh_s(ji,jk) = h_s_1d(ji) * r1_nlay_s |
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| 161 | END DO |
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| 162 | END DO |
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| 163 | |
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[9274] | 164 | ! ! ============ ! |
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| 165 | ! ! Snow ! |
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| 166 | ! ! ============ ! |
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| 167 | ! |
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| 168 | ! Internal melting |
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| 169 | ! ---------------- |
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| 170 | ! IF snow temperature is above freezing point, THEN snow melts (should not happen but sometimes it does) |
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[9271] | 171 | DO jk = 1, nlay_s |
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[8586] | 172 | DO ji = 1, npti |
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[9274] | 173 | IF( t_s_1d(ji,jk) > rt0 ) THEN |
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| 174 | hfx_res_1d (ji) = hfx_res_1d (ji) + e_s_1d(ji,jk) * zh_s(ji,jk) * a_i_1d(ji) * r1_rdtice ! heat flux to the ocean [W.m-2], < 0 |
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[9935] | 175 | wfx_snw_sum_1d(ji) = wfx_snw_sum_1d(ji) + rhos * zh_s(ji,jk) * a_i_1d(ji) * r1_rdtice ! mass flux |
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[9271] | 176 | ! updates |
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[9274] | 177 | dh_s_mlt(ji) = dh_s_mlt(ji) - zh_s(ji,jk) |
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| 178 | h_s_1d (ji) = h_s_1d(ji) - zh_s(ji,jk) |
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| 179 | zh_s (ji,jk) = 0._wp |
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| 180 | e_s_1d (ji,jk) = 0._wp |
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| 181 | t_s_1d (ji,jk) = rt0 |
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[9271] | 182 | END IF |
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[8586] | 183 | END DO |
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[9274] | 184 | END DO |
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[8586] | 185 | |
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[9274] | 186 | ! Snow precipitation |
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| 187 | !------------------- |
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| 188 | CALL ice_thd_snwblow( 1. - at_i_1d(1:npti), zsnw(1:npti) ) ! snow distribution over ice after wind blowing |
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[8586] | 189 | |
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| 190 | zdeltah(1:npti,:) = 0._wp |
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| 191 | DO ji = 1, npti |
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[9274] | 192 | IF( sprecip_1d(ji) > 0._wp ) THEN |
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| 193 | ! |
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| 194 | ! --- precipitation --- |
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[9935] | 195 | zdh_s_pre (ji) = zsnw(ji) * sprecip_1d(ji) * rdt_ice * r1_rhos / at_i_1d(ji) ! thickness change |
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[9274] | 196 | zqprec (ji) = - qprec_ice_1d(ji) ! enthalpy of the precip (>0, J.m-3) |
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| 197 | ! |
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| 198 | hfx_spr_1d(ji) = hfx_spr_1d(ji) + zdh_s_pre(ji) * a_i_1d(ji) * zqprec(ji) * r1_rdtice ! heat flux from snow precip (>0, W.m-2) |
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[9935] | 199 | wfx_spr_1d(ji) = wfx_spr_1d(ji) - rhos * a_i_1d(ji) * zdh_s_pre(ji) * r1_rdtice ! mass flux, <0 |
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[9274] | 200 | |
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| 201 | ! --- melt of falling snow --- |
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| 202 | rswitch = MAX( 0._wp , SIGN( 1._wp , zqprec(ji) - epsi20 ) ) |
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[9922] | 203 | zdeltah (ji,1) = - rswitch * zq_top(ji) / MAX( zqprec(ji) , epsi20 ) ! thickness change |
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| 204 | zdeltah (ji,1) = MAX( - zdh_s_pre(ji), zdeltah(ji,1) ) ! bound melting |
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[9274] | 205 | hfx_snw_1d (ji) = hfx_snw_1d (ji) - zdeltah(ji,1) * a_i_1d(ji) * zqprec(ji) * r1_rdtice ! heat used to melt snow (W.m-2, >0) |
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[9935] | 206 | wfx_snw_sum_1d(ji) = wfx_snw_sum_1d(ji) - rhos * a_i_1d(ji) * zdeltah(ji,1) * r1_rdtice ! snow melting only = water into the ocean (then without snow precip), >0 |
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[9274] | 207 | |
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| 208 | ! updates available heat + precipitations after melting |
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| 209 | dh_s_mlt (ji) = dh_s_mlt(ji) + zdeltah(ji,1) |
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[9922] | 210 | zq_top (ji) = MAX( 0._wp , zq_top (ji) + zdeltah(ji,1) * zqprec(ji) ) |
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[9274] | 211 | zdh_s_pre(ji) = zdh_s_pre(ji) + zdeltah(ji,1) |
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| 212 | |
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| 213 | ! update thickness |
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| 214 | h_s_1d(ji) = MAX( 0._wp , h_s_1d(ji) + zdh_s_pre(ji) ) |
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| 215 | ! |
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| 216 | ELSE |
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| 217 | ! |
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| 218 | zdh_s_pre(ji) = 0._wp |
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| 219 | zqprec (ji) = 0._wp |
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| 220 | ! |
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| 221 | ENDIF |
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[8586] | 222 | END DO |
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| 223 | |
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[9271] | 224 | ! recalculate snow layers |
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| 225 | DO jk = 1, nlay_s |
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| 226 | DO ji = 1, npti |
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| 227 | zh_s(ji,jk) = h_s_1d(ji) * r1_nlay_s |
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| 228 | END DO |
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| 229 | END DO |
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| 230 | |
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[9274] | 231 | ! Snow melting |
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| 232 | ! ------------ |
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[9922] | 233 | ! If heat still available (zq_top > 0), then melt more snow |
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[8586] | 234 | zdeltah(1:npti,:) = 0._wp |
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| 235 | zdh_s_mel(1:npti) = 0._wp |
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| 236 | DO jk = 1, nlay_s |
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| 237 | DO ji = 1, npti |
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[9922] | 238 | IF( zh_s(ji,jk) > 0._wp .AND. zq_top(ji) > 0._wp ) THEN |
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[9274] | 239 | ! |
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| 240 | rswitch = MAX( 0._wp, SIGN( 1._wp, e_s_1d(ji,jk) - epsi20 ) ) |
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[9922] | 241 | zdeltah (ji,jk) = - rswitch * zq_top(ji) / MAX( e_s_1d(ji,jk), epsi20 ) ! thickness change |
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| 242 | zdeltah (ji,jk) = MAX( zdeltah(ji,jk) , - zh_s(ji,jk) ) ! bound melting |
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[9274] | 243 | zdh_s_mel(ji) = zdh_s_mel(ji) + zdeltah(ji,jk) |
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| 244 | |
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| 245 | hfx_snw_1d(ji) = hfx_snw_1d(ji) - zdeltah(ji,jk) * a_i_1d(ji) * e_s_1d (ji,jk) * r1_rdtice ! heat used to melt snow(W.m-2, >0) |
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[9935] | 246 | wfx_snw_sum_1d(ji) = wfx_snw_sum_1d(ji) - rhos * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice ! snow melting only = water into the ocean (then without snow precip) |
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[9274] | 247 | |
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| 248 | ! updates available heat + thickness |
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| 249 | dh_s_mlt(ji) = dh_s_mlt(ji) + zdeltah(ji,jk) |
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[9922] | 250 | zq_top (ji) = MAX( 0._wp , zq_top(ji) + zdeltah(ji,jk) * e_s_1d(ji,jk) ) |
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[9274] | 251 | h_s_1d (ji) = MAX( 0._wp , h_s_1d(ji) + zdeltah(ji,jk) ) |
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| 252 | zh_s (ji,jk) = MAX( 0._wp , zh_s(ji,jk) + zdeltah(ji,jk) ) |
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| 253 | ! |
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| 254 | ENDIF |
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[8586] | 255 | END DO |
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| 256 | END DO |
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| 257 | |
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[9274] | 258 | ! Snow sublimation |
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| 259 | !----------------- |
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[8586] | 260 | ! qla_ice is always >=0 (upwards), heat goes to the atmosphere, therefore snow sublimates |
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[8885] | 261 | ! comment: not counted in mass/heat exchange in iceupdate.F90 since this is an exchange with atm. (not ocean) |
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[8586] | 262 | zdeltah(1:npti,:) = 0._wp |
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| 263 | DO ji = 1, npti |
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[9274] | 264 | IF( evap_ice_1d(ji) > 0._wp ) THEN |
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| 265 | ! |
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[9935] | 266 | zdh_s_sub (ji) = MAX( - h_s_1d(ji) , - evap_ice_1d(ji) * r1_rhos * rdt_ice ) |
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| 267 | zevap_rema(ji) = evap_ice_1d(ji) * rdt_ice + zdh_s_sub(ji) * rhos ! remaining evap in kg.m-2 (used for ice melting later on) |
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[9274] | 268 | zdeltah (ji,1) = MAX( zdh_s_sub(ji), - zdh_s_pre(ji) ) |
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| 269 | |
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| 270 | hfx_sub_1d (ji) = hfx_sub_1d(ji) + & ! Heat flux by sublimation [W.m-2], < 0 (sublimate snow that had fallen, then pre-existing snow) |
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| 271 | & ( zdeltah(ji,1) * zqprec(ji) + ( zdh_s_sub(ji) - zdeltah(ji,1) ) * e_s_1d(ji,1) ) & |
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| 272 | & * a_i_1d(ji) * r1_rdtice |
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[9935] | 273 | wfx_snw_sub_1d(ji) = wfx_snw_sub_1d(ji) - rhos * a_i_1d(ji) * zdh_s_sub(ji) * r1_rdtice ! Mass flux by sublimation |
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[9274] | 274 | |
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| 275 | ! new snow thickness |
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| 276 | h_s_1d(ji) = MAX( 0._wp , h_s_1d(ji) + zdh_s_sub(ji) ) |
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| 277 | ! update precipitations after sublimation and correct sublimation |
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| 278 | zdh_s_pre(ji) = zdh_s_pre(ji) + zdeltah(ji,1) |
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| 279 | zdh_s_sub(ji) = zdh_s_sub(ji) - zdeltah(ji,1) |
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| 280 | ! |
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| 281 | ELSE |
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| 282 | ! |
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| 283 | zdh_s_sub (ji) = 0._wp |
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| 284 | zevap_rema(ji) = 0._wp |
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| 285 | ! |
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| 286 | ENDIF |
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[8586] | 287 | END DO |
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| 288 | |
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| 289 | ! --- Update snow diags --- ! |
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| 290 | DO ji = 1, npti |
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| 291 | dh_s_tot(ji) = zdh_s_mel(ji) + zdh_s_pre(ji) + zdh_s_sub(ji) |
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| 292 | END DO |
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| 293 | |
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[9274] | 294 | ! Update temperature, energy |
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| 295 | !--------------------------- |
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[8586] | 296 | ! new temp and enthalpy of the snow (remaining snow precip + remaining pre-existing snow) |
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| 297 | DO jk = 1, nlay_s |
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| 298 | DO ji = 1,npti |
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| 299 | rswitch = MAX( 0._wp , SIGN( 1._wp, h_s_1d(ji) - epsi20 ) ) |
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[9274] | 300 | e_s_1d(ji,jk) = rswitch / MAX( h_s_1d(ji), epsi20 ) * & |
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| 301 | & ( ( zdh_s_pre(ji) ) * zqprec(ji) + & |
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[9935] | 302 | & ( h_s_1d(ji) - zdh_s_pre(ji) ) * rhos * ( rcpi * ( rt0 - t_s_1d(ji,jk) ) + rLfus ) ) |
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[8586] | 303 | END DO |
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| 304 | END DO |
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[9274] | 305 | |
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| 306 | ! ! ============ ! |
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| 307 | ! ! Ice ! |
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| 308 | ! ! ============ ! |
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[8586] | 309 | |
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[9274] | 310 | ! Surface ice melting |
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| 311 | !-------------------- |
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[8586] | 312 | zdeltah(1:npti,:) = 0._wp ! important |
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| 313 | DO jk = 1, nlay_i |
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| 314 | DO ji = 1, npti |
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[9935] | 315 | ztmelts = - rTmlt * sz_i_1d(ji,jk) ! Melting point of layer k [C] |
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[8586] | 316 | |
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[9274] | 317 | IF( t_i_1d(ji,jk) >= (ztmelts+rt0) ) THEN !-- Internal melting |
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[8586] | 318 | |
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[9935] | 319 | zEi = - e_i_1d(ji,jk) * r1_rhoi ! Specific enthalpy of layer k [J/kg, <0] |
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[9274] | 320 | zdE = 0._wp ! Specific enthalpy difference (J/kg, <0) |
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[8586] | 321 | ! set up at 0 since no energy is needed to melt water...(it is already melted) |
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| 322 | zdeltah(ji,jk) = MIN( 0._wp , - zh_i(ji,jk) ) ! internal melting occurs when the internal temperature is above freezing |
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| 323 | ! this should normally not happen, but sometimes, heat diffusion leads to this |
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[9935] | 324 | zfmdt = - zdeltah(ji,jk) * rhoi ! Mass flux x time step > 0 |
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[8586] | 325 | |
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[9750] | 326 | dh_i_itm(ji) = dh_i_itm(ji) + zdeltah(ji,jk) ! Cumulate internal melting |
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[8586] | 327 | |
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[9935] | 328 | zfmdt = - rhoi * zdeltah(ji,jk) ! Recompute mass flux [kg/m2, >0] |
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[8586] | 329 | |
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[9274] | 330 | hfx_res_1d(ji) = hfx_res_1d(ji) + zfmdt * a_i_1d(ji) * zEi * r1_rdtice ! Heat flux to the ocean [W.m-2], <0 |
---|
| 331 | ! ice enthalpy zEi is "sent" to the ocean |
---|
[9935] | 332 | sfx_res_1d(ji) = sfx_res_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * s_i_1d(ji) * r1_rdtice ! Salt flux |
---|
[9274] | 333 | ! using s_i_1d and not sz_i_1d(jk) is ok |
---|
[9935] | 334 | wfx_res_1d(ji) = wfx_res_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice ! Mass flux |
---|
[8586] | 335 | |
---|
[9274] | 336 | ELSE !-- Surface melting |
---|
[8586] | 337 | |
---|
[9935] | 338 | zEi = - e_i_1d(ji,jk) * r1_rhoi ! Specific enthalpy of layer k [J/kg, <0] |
---|
[8586] | 339 | zEw = rcp * ztmelts ! Specific enthalpy of resulting meltwater [J/kg, <0] |
---|
| 340 | zdE = zEi - zEw ! Specific enthalpy difference < 0 |
---|
| 341 | |
---|
[9922] | 342 | zfmdt = - zq_top(ji) / zdE ! Mass flux to the ocean [kg/m2, >0] |
---|
[8586] | 343 | |
---|
[9935] | 344 | zdeltah(ji,jk) = - zfmdt * r1_rhoi ! Melt of layer jk [m, <0] |
---|
[8586] | 345 | |
---|
| 346 | zdeltah(ji,jk) = MIN( 0._wp , MAX( zdeltah(ji,jk) , - zh_i(ji,jk) ) ) ! Melt of layer jk cannot exceed the layer thickness [m, <0] |
---|
| 347 | |
---|
[9935] | 348 | zq_top(ji) = MAX( 0._wp , zq_top(ji) - zdeltah(ji,jk) * rhoi * zdE ) ! update available heat |
---|
[8586] | 349 | |
---|
[9750] | 350 | dh_i_sum(ji) = dh_i_sum(ji) + zdeltah(ji,jk) ! Cumulate surface melt |
---|
[8586] | 351 | |
---|
[9935] | 352 | zfmdt = - rhoi * zdeltah(ji,jk) ! Recompute mass flux [kg/m2, >0] |
---|
[8586] | 353 | |
---|
| 354 | zQm = zfmdt * zEw ! Energy of the melt water sent to the ocean [J/m2, <0] |
---|
| 355 | |
---|
[9935] | 356 | sfx_sum_1d(ji) = sfx_sum_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * s_i_1d(ji) * r1_rdtice ! Salt flux >0 |
---|
[9274] | 357 | ! using s_i_1d and not sz_i_1d(jk) is ok) |
---|
| 358 | hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice ! Heat flux [W.m-2], < 0 |
---|
| 359 | hfx_sum_1d(ji) = hfx_sum_1d(ji) - zfmdt * a_i_1d(ji) * zdE * r1_rdtice ! Heat flux used in this process [W.m-2], > 0 |
---|
| 360 | ! |
---|
[9935] | 361 | wfx_sum_1d(ji) = wfx_sum_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice ! Mass flux |
---|
[8586] | 362 | |
---|
| 363 | END IF |
---|
[9274] | 364 | |
---|
| 365 | ! Ice sublimation |
---|
| 366 | ! --------------- |
---|
[9935] | 367 | zdum = MAX( - ( zh_i(ji,jk) + zdeltah(ji,jk) ) , - zevap_rema(ji) * r1_rhoi ) |
---|
[9274] | 368 | zdeltah (ji,jk) = zdeltah (ji,jk) + zdum |
---|
| 369 | dh_i_sub(ji) = dh_i_sub(ji) + zdum |
---|
| 370 | |
---|
[9935] | 371 | sfx_sub_1d(ji) = sfx_sub_1d(ji) - rhoi * a_i_1d(ji) * zdum * s_i_1d(ji) * r1_rdtice ! Salt flux >0 |
---|
[9274] | 372 | ! clem: flux is sent to the ocean for simplicity |
---|
| 373 | ! but salt should remain in the ice except |
---|
| 374 | ! if all ice is melted. => must be corrected |
---|
| 375 | hfx_sub_1d(ji) = hfx_sub_1d(ji) + zdum * e_i_1d(ji,jk) * a_i_1d(ji) * r1_rdtice ! Heat flux [W.m-2], < 0 |
---|
[8586] | 376 | |
---|
[9935] | 377 | wfx_ice_sub_1d(ji) = wfx_ice_sub_1d(ji) - rhoi * a_i_1d(ji) * zdum * r1_rdtice ! Mass flux > 0 |
---|
[9274] | 378 | |
---|
[8586] | 379 | ! update remaining mass flux |
---|
[9935] | 380 | zevap_rema(ji) = zevap_rema(ji) + zdum * rhoi |
---|
[8586] | 381 | |
---|
| 382 | ! record which layers have disappeared (for bottom melting) |
---|
| 383 | ! => icount=0 : no layer has vanished |
---|
| 384 | ! => icount=5 : 5 layers have vanished |
---|
| 385 | rswitch = MAX( 0._wp , SIGN( 1._wp , - ( zh_i(ji,jk) + zdeltah(ji,jk) ) ) ) |
---|
| 386 | icount(ji,jk) = NINT( rswitch ) |
---|
| 387 | zh_i(ji,jk) = MAX( 0._wp , zh_i(ji,jk) + zdeltah(ji,jk) ) |
---|
| 388 | |
---|
| 389 | ! update heat content (J.m-2) and layer thickness |
---|
| 390 | eh_i_old(ji,jk) = eh_i_old(ji,jk) + zdeltah(ji,jk) * e_i_1d(ji,jk) |
---|
| 391 | h_i_old (ji,jk) = h_i_old (ji,jk) + zdeltah(ji,jk) |
---|
| 392 | END DO |
---|
| 393 | END DO |
---|
[9274] | 394 | |
---|
[8586] | 395 | ! update ice thickness |
---|
| 396 | DO ji = 1, npti |
---|
[9750] | 397 | h_i_1d(ji) = MAX( 0._wp , h_i_1d(ji) + dh_i_sum(ji) + dh_i_itm(ji) + dh_i_sub(ji) ) |
---|
[8586] | 398 | END DO |
---|
| 399 | |
---|
| 400 | ! remaining "potential" evap is sent to ocean |
---|
| 401 | DO ji = 1, npti |
---|
| 402 | wfx_err_sub_1d(ji) = wfx_err_sub_1d(ji) - zevap_rema(ji) * a_i_1d(ji) * r1_rdtice ! <=0 (net evap for the ocean in kg.m-2.s-1) |
---|
| 403 | END DO |
---|
| 404 | |
---|
| 405 | |
---|
[9274] | 406 | ! Ice Basal growth |
---|
[8586] | 407 | !------------------ |
---|
| 408 | ! Basal growth is driven by heat imbalance at the ice-ocean interface, |
---|
[9916] | 409 | ! between the inner conductive flux (qcn_ice_bot), from the open water heat flux |
---|
[9913] | 410 | ! (fhld) and the sensible ice-ocean flux (qsb_ice_bot). |
---|
[9916] | 411 | ! qcn_ice_bot is positive downwards. qsb_ice_bot and fhld are positive to the ice |
---|
[8586] | 412 | |
---|
| 413 | ! If salinity varies in time, an iterative procedure is required, because |
---|
| 414 | ! the involved quantities are inter-dependent. |
---|
[9750] | 415 | ! Basal growth (dh_i_bog) depends upon new ice specific enthalpy (zEi), |
---|
| 416 | ! which depends on forming ice salinity (s_i_new), which depends on dh/dt (dh_i_bog) |
---|
[8586] | 417 | ! -> need for an iterative procedure, which converges quickly |
---|
| 418 | |
---|
| 419 | num_iter_max = 1 |
---|
| 420 | IF( nn_icesal == 2 ) num_iter_max = 5 ! salinity varying in time |
---|
| 421 | |
---|
| 422 | DO ji = 1, npti |
---|
| 423 | IF( zf_tt(ji) < 0._wp ) THEN |
---|
[9274] | 424 | DO iter = 1, num_iter_max ! iterations |
---|
[8586] | 425 | |
---|
| 426 | ! New bottom ice salinity (Cox & Weeks, JGR88 ) |
---|
| 427 | !--- zswi1 if dh/dt < 2.0e-8 |
---|
| 428 | !--- zswi12 if 2.0e-8 < dh/dt < 3.6e-7 |
---|
| 429 | !--- zswi2 if dh/dt > 3.6e-7 |
---|
[9750] | 430 | zgrr = MIN( 1.0e-3, MAX ( dh_i_bog(ji) * r1_rdtice , epsi10 ) ) |
---|
[9274] | 431 | zswi2 = MAX( 0._wp , SIGN( 1._wp , zgrr - 3.6e-7 ) ) |
---|
| 432 | zswi12 = MAX( 0._wp , SIGN( 1._wp , zgrr - 2.0e-8 ) ) * ( 1.0 - zswi2 ) |
---|
| 433 | zswi1 = 1. - zswi2 * zswi12 |
---|
| 434 | zfracs = MIN( zswi1 * 0.12 + zswi12 * ( 0.8925 + 0.0568 * LOG( 100.0 * zgrr ) ) & |
---|
| 435 | & + zswi2 * 0.26 / ( 0.26 + 0.74 * EXP ( - 724300.0 * zgrr ) ) , 0.5 ) |
---|
[8586] | 436 | |
---|
[9274] | 437 | s_i_new(ji) = zswitch_sal * zfracs * sss_1d(ji) + ( 1. - zswitch_sal ) * s_i_1d(ji) ! New ice salinity |
---|
[8586] | 438 | |
---|
[9935] | 439 | ztmelts = - rTmlt * s_i_new(ji) ! New ice melting point (C) |
---|
[9274] | 440 | |
---|
| 441 | zt_i_new = zswitch_sal * t_bo_1d(ji) + ( 1. - zswitch_sal) * t_i_1d(ji, nlay_i) |
---|
[8586] | 442 | |
---|
[9935] | 443 | zEi = rcpi * ( zt_i_new - (ztmelts+rt0) ) & ! Specific enthalpy of forming ice (J/kg, <0) |
---|
| 444 | & - rLfus * ( 1.0 - ztmelts / ( zt_i_new - rt0 ) ) + rcp * ztmelts |
---|
[8586] | 445 | |
---|
[9274] | 446 | zEw = rcp * ( t_bo_1d(ji) - rt0 ) ! Specific enthalpy of seawater (J/kg, < 0) |
---|
[8586] | 447 | |
---|
[9274] | 448 | zdE = zEi - zEw ! Specific enthalpy difference (J/kg, <0) |
---|
[8586] | 449 | |
---|
[9935] | 450 | dh_i_bog(ji) = rdt_ice * MAX( 0._wp , zf_tt(ji) / ( zdE * rhoi ) ) |
---|
[8586] | 451 | |
---|
| 452 | END DO |
---|
| 453 | ! Contribution to Energy and Salt Fluxes |
---|
[9935] | 454 | zfmdt = - rhoi * dh_i_bog(ji) ! Mass flux x time step (kg/m2, < 0) |
---|
[8586] | 455 | |
---|
[9274] | 456 | hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice ! Heat flux to the ocean [W.m-2], >0 |
---|
| 457 | hfx_bog_1d(ji) = hfx_bog_1d(ji) - zfmdt * a_i_1d(ji) * zdE * r1_rdtice ! Heat flux used in this process [W.m-2], <0 |
---|
[8586] | 458 | |
---|
[9935] | 459 | sfx_bog_1d(ji) = sfx_bog_1d(ji) - rhoi * a_i_1d(ji) * dh_i_bog(ji) * s_i_new(ji) * r1_rdtice ! Salt flux, <0 |
---|
[8586] | 460 | |
---|
[9935] | 461 | wfx_bog_1d(ji) = wfx_bog_1d(ji) - rhoi * a_i_1d(ji) * dh_i_bog(ji) * r1_rdtice ! Mass flux, <0 |
---|
[8586] | 462 | |
---|
| 463 | ! update heat content (J.m-2) and layer thickness |
---|
[9935] | 464 | eh_i_old(ji,nlay_i+1) = eh_i_old(ji,nlay_i+1) + dh_i_bog(ji) * (-zEi * rhoi) |
---|
[9750] | 465 | h_i_old (ji,nlay_i+1) = h_i_old (ji,nlay_i+1) + dh_i_bog(ji) |
---|
[8586] | 466 | |
---|
| 467 | ENDIF |
---|
| 468 | |
---|
| 469 | END DO |
---|
| 470 | |
---|
[9274] | 471 | ! Ice Basal melt |
---|
| 472 | !--------------- |
---|
[8586] | 473 | zdeltah(1:npti,:) = 0._wp ! important |
---|
| 474 | DO jk = nlay_i, 1, -1 |
---|
| 475 | DO ji = 1, npti |
---|
| 476 | IF( zf_tt(ji) > 0._wp .AND. jk > icount(ji,jk) ) THEN ! do not calculate where layer has already disappeared by surface melting |
---|
| 477 | |
---|
[9935] | 478 | ztmelts = - rTmlt * sz_i_1d(ji,jk) ! Melting point of layer jk (C) |
---|
[8586] | 479 | |
---|
[9274] | 480 | IF( t_i_1d(ji,jk) >= (ztmelts+rt0) ) THEN !-- Internal melting |
---|
[8586] | 481 | |
---|
[9935] | 482 | zEi = - e_i_1d(ji,jk) * r1_rhoi ! Specific enthalpy of melting ice (J/kg, <0) |
---|
[8586] | 483 | zdE = 0._wp ! Specific enthalpy difference (J/kg, <0) |
---|
[9274] | 484 | ! set up at 0 since no energy is needed to melt water...(it is already melted) |
---|
[8586] | 485 | zdeltah (ji,jk) = MIN( 0._wp , - zh_i(ji,jk) ) ! internal melting occurs when the internal temperature is above freezing |
---|
| 486 | ! this should normally not happen, but sometimes, heat diffusion leads to this |
---|
| 487 | |
---|
[9750] | 488 | dh_i_itm (ji) = dh_i_itm(ji) + zdeltah(ji,jk) |
---|
[8586] | 489 | |
---|
[9935] | 490 | zfmdt = - zdeltah(ji,jk) * rhoi ! Mass flux x time step > 0 |
---|
[8586] | 491 | |
---|
[9274] | 492 | hfx_res_1d(ji) = hfx_res_1d(ji) + zfmdt * a_i_1d(ji) * zEi * r1_rdtice ! Heat flux to the ocean [W.m-2], <0 |
---|
| 493 | ! ice enthalpy zEi is "sent" to the ocean |
---|
[9935] | 494 | sfx_res_1d(ji) = sfx_res_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * s_i_1d(ji) * r1_rdtice ! Salt flux |
---|
[9274] | 495 | ! using s_i_1d and not sz_i_1d(jk) is ok |
---|
[9935] | 496 | wfx_res_1d(ji) = wfx_res_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice ! Mass flux |
---|
[8586] | 497 | |
---|
| 498 | ! update heat content (J.m-2) and layer thickness |
---|
| 499 | eh_i_old(ji,jk) = eh_i_old(ji,jk) + zdeltah(ji,jk) * e_i_1d(ji,jk) |
---|
| 500 | h_i_old (ji,jk) = h_i_old (ji,jk) + zdeltah(ji,jk) |
---|
| 501 | |
---|
[9274] | 502 | ELSE !-- Basal melting |
---|
[8586] | 503 | |
---|
[9935] | 504 | zEi = - e_i_1d(ji,jk) * r1_rhoi ! Specific enthalpy of melting ice (J/kg, <0) |
---|
[9274] | 505 | zEw = rcp * ztmelts ! Specific enthalpy of meltwater (J/kg, <0) |
---|
| 506 | zdE = zEi - zEw ! Specific enthalpy difference (J/kg, <0) |
---|
[8586] | 507 | |
---|
[9922] | 508 | zfmdt = - zq_bot(ji) / zdE ! Mass flux x time step (kg/m2, >0) |
---|
[8586] | 509 | |
---|
[9935] | 510 | zdeltah(ji,jk) = - zfmdt * r1_rhoi ! Gross thickness change |
---|
[8586] | 511 | |
---|
[9274] | 512 | zdeltah(ji,jk) = MIN( 0._wp , MAX( zdeltah(ji,jk), - zh_i(ji,jk) ) ) ! bound thickness change |
---|
[8586] | 513 | |
---|
[9935] | 514 | zq_bot(ji) = MAX( 0._wp , zq_bot(ji) - zdeltah(ji,jk) * rhoi * zdE ) ! update available heat. MAX is necessary for roundup errors |
---|
[8586] | 515 | |
---|
[9922] | 516 | dh_i_bom(ji) = dh_i_bom(ji) + zdeltah(ji,jk) ! Update basal melt |
---|
[8586] | 517 | |
---|
[9935] | 518 | zfmdt = - zdeltah(ji,jk) * rhoi ! Mass flux x time step > 0 |
---|
[8586] | 519 | |
---|
[9274] | 520 | zQm = zfmdt * zEw ! Heat exchanged with ocean |
---|
[8586] | 521 | |
---|
[9274] | 522 | hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice ! Heat flux to the ocean [W.m-2], <0 |
---|
| 523 | hfx_bom_1d(ji) = hfx_bom_1d(ji) - zfmdt * a_i_1d(ji) * zdE * r1_rdtice ! Heat used in this process [W.m-2], >0 |
---|
[8586] | 524 | |
---|
[9935] | 525 | sfx_bom_1d(ji) = sfx_bom_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * s_i_1d(ji) * r1_rdtice ! Salt flux |
---|
[9274] | 526 | ! using s_i_1d and not sz_i_1d(jk) is ok |
---|
[8586] | 527 | |
---|
[9935] | 528 | wfx_bom_1d(ji) = wfx_bom_1d(ji) - rhoi * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice ! Mass flux |
---|
[8586] | 529 | |
---|
| 530 | ! update heat content (J.m-2) and layer thickness |
---|
| 531 | eh_i_old(ji,jk) = eh_i_old(ji,jk) + zdeltah(ji,jk) * e_i_1d(ji,jk) |
---|
| 532 | h_i_old (ji,jk) = h_i_old (ji,jk) + zdeltah(ji,jk) |
---|
| 533 | ENDIF |
---|
| 534 | |
---|
| 535 | ENDIF |
---|
| 536 | END DO |
---|
| 537 | END DO |
---|
| 538 | |
---|
| 539 | ! Update temperature, energy |
---|
[9274] | 540 | ! -------------------------- |
---|
[8586] | 541 | DO ji = 1, npti |
---|
[9750] | 542 | h_i_1d(ji) = MAX( 0._wp , h_i_1d(ji) + dh_i_bog(ji) + dh_i_bom(ji) ) |
---|
[8586] | 543 | END DO |
---|
| 544 | |
---|
[9274] | 545 | ! If heat still available then melt more snow |
---|
[8586] | 546 | !------------------------------------------- |
---|
| 547 | zdeltah(1:npti,:) = 0._wp ! important |
---|
| 548 | DO ji = 1, npti |
---|
[9922] | 549 | zq_rema (ji) = zq_top(ji) + zq_bot(ji) |
---|
[9274] | 550 | rswitch = 1._wp - MAX( 0._wp, SIGN( 1._wp, - h_s_1d(ji) ) ) ! =1 if snow |
---|
| 551 | rswitch = rswitch * MAX( 0._wp, SIGN( 1._wp, e_s_1d(ji,1) - epsi20 ) ) |
---|
| 552 | zdeltah (ji,1) = - rswitch * zq_rema(ji) / MAX( e_s_1d(ji,1), epsi20 ) |
---|
| 553 | zdeltah (ji,1) = MIN( 0._wp , MAX( zdeltah(ji,1) , - h_s_1d(ji) ) ) ! bound melting |
---|
| 554 | dh_s_tot(ji) = dh_s_tot(ji) + zdeltah(ji,1) |
---|
| 555 | h_s_1d (ji) = h_s_1d (ji) + zdeltah(ji,1) |
---|
[8586] | 556 | |
---|
[9274] | 557 | zq_rema(ji) = zq_rema(ji) + zdeltah(ji,1) * e_s_1d(ji,1) ! update available heat (J.m-2) |
---|
| 558 | hfx_snw_1d(ji) = hfx_snw_1d(ji) - zdeltah(ji,1) * a_i_1d(ji) * e_s_1d(ji,1) * r1_rdtice ! Heat used to melt snow, W.m-2 (>0) |
---|
[9935] | 559 | wfx_snw_sum_1d(ji) = wfx_snw_sum_1d(ji) - rhos * a_i_1d(ji) * zdeltah(ji,1) * r1_rdtice ! Mass flux |
---|
[8637] | 560 | dh_s_mlt(ji) = dh_s_mlt(ji) + zdeltah(ji,1) |
---|
[8586] | 561 | ! |
---|
| 562 | ! Remaining heat flux (W.m-2) is sent to the ocean heat budget |
---|
[9912] | 563 | qt_oce_ai_1d(ji) = qt_oce_ai_1d(ji) + ( zq_rema(ji) * a_i_1d(ji) ) * r1_rdtice |
---|
[8586] | 564 | |
---|
| 565 | IF( ln_icectl .AND. zq_rema(ji) < 0. .AND. lwp ) WRITE(numout,*) 'ALERTE zq_rema <0 = ', zq_rema(ji) |
---|
| 566 | END DO |
---|
| 567 | |
---|
| 568 | ! |
---|
[9274] | 569 | ! Snow-Ice formation |
---|
| 570 | ! ------------------ |
---|
[8586] | 571 | ! When snow load excesses Archimede's limit, snow-ice interface goes down under sea-level, |
---|
| 572 | ! flooding of seawater transforms snow into ice dh_snowice is positive for the ice |
---|
[9935] | 573 | z1_rho = 1._wp / ( rhos+rau0-rhoi ) |
---|
[8586] | 574 | DO ji = 1, npti |
---|
| 575 | ! |
---|
[9935] | 576 | dh_snowice(ji) = MAX( 0._wp , ( rhos * h_s_1d(ji) + (rhoi-rau0) * h_i_1d(ji) ) * z1_rho ) |
---|
[8586] | 577 | |
---|
| 578 | h_i_1d(ji) = h_i_1d(ji) + dh_snowice(ji) |
---|
| 579 | h_s_1d(ji) = h_s_1d(ji) - dh_snowice(ji) |
---|
| 580 | |
---|
| 581 | ! Contribution to energy flux to the ocean [J/m2], >0 (if sst<0) |
---|
[9935] | 582 | zfmdt = ( rhos - rhoi ) * dh_snowice(ji) ! <0 |
---|
[8586] | 583 | zEw = rcp * sst_1d(ji) |
---|
| 584 | zQm = zfmdt * zEw |
---|
| 585 | |
---|
[9274] | 586 | hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice ! Heat flux |
---|
[8586] | 587 | |
---|
[9274] | 588 | sfx_sni_1d(ji) = sfx_sni_1d(ji) + sss_1d(ji) * a_i_1d(ji) * zfmdt * r1_rdtice ! Salt flux |
---|
[8586] | 589 | |
---|
| 590 | ! Case constant salinity in time: virtual salt flux to keep salinity constant |
---|
[8637] | 591 | IF( nn_icesal /= 2 ) THEN |
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[8586] | 592 | sfx_bri_1d(ji) = sfx_bri_1d(ji) - sss_1d (ji) * a_i_1d(ji) * zfmdt * r1_rdtice & ! put back sss_m into the ocean |
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[9935] | 593 | & - s_i_1d(ji) * a_i_1d(ji) * dh_snowice(ji) * rhoi * r1_rdtice ! and get rn_icesal from the ocean |
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[8586] | 594 | ENDIF |
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| 595 | |
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[9274] | 596 | ! Mass flux: All snow is thrown in the ocean, and seawater is taken to replace the volume |
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[9935] | 597 | wfx_sni_1d(ji) = wfx_sni_1d(ji) - a_i_1d(ji) * dh_snowice(ji) * rhoi * r1_rdtice |
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| 598 | wfx_snw_sni_1d(ji) = wfx_snw_sni_1d(ji) + a_i_1d(ji) * dh_snowice(ji) * rhos * r1_rdtice |
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[8586] | 599 | |
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| 600 | ! update heat content (J.m-2) and layer thickness |
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| 601 | eh_i_old(ji,0) = eh_i_old(ji,0) + dh_snowice(ji) * e_s_1d(ji,1) + zfmdt * zEw |
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| 602 | h_i_old (ji,0) = h_i_old (ji,0) + dh_snowice(ji) |
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| 603 | |
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| 604 | END DO |
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| 605 | |
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| 606 | ! |
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| 607 | ! Update temperature, energy |
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[9274] | 608 | ! -------------------------- |
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[8586] | 609 | DO ji = 1, npti |
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[9274] | 610 | rswitch = 1._wp - MAX( 0._wp , SIGN( 1._wp , - h_i_1d(ji) ) ) |
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| 611 | t_su_1d(ji) = rswitch * t_su_1d(ji) + ( 1._wp - rswitch ) * rt0 |
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[8586] | 612 | END DO |
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| 613 | |
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| 614 | DO jk = 1, nlay_s |
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| 615 | DO ji = 1,npti |
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[10786] | 616 | ! where there is no ice or no snow |
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| 617 | rswitch = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, - h_s_1d(ji) ) ) ) * ( 1._wp - MAX( 0._wp, SIGN(1._wp, - h_i_1d(ji) ) ) ) |
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| 618 | ! mass & energy loss to the ocean |
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| 619 | hfx_res_1d(ji) = hfx_res_1d(ji) + ( 1._wp - rswitch ) * & |
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| 620 | & ( e_s_1d(ji,jk) * h_s_1d(ji) * r1_nlay_s * a_i_1d(ji) * r1_rdtice ) ! heat flux to the ocean [W.m-2], < 0 |
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| 621 | wfx_res_1d(ji) = wfx_res_1d(ji) + ( 1._wp - rswitch ) * & |
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| 622 | & ( rhos * h_s_1d(ji) * r1_nlay_s * a_i_1d(ji) * r1_rdtice ) ! mass flux |
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| 623 | ! update energy (mass is updated in the next loop) |
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[8586] | 624 | e_s_1d(ji,jk) = rswitch * e_s_1d(ji,jk) |
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| 625 | ! recalculate t_s_1d from e_s_1d |
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[9935] | 626 | t_s_1d(ji,jk) = rt0 + rswitch * ( - e_s_1d(ji,jk) * r1_rhos * r1_rcpi + rLfus * r1_rcpi ) |
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[8586] | 627 | END DO |
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| 628 | END DO |
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| 629 | |
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[10786] | 630 | ! --- ensure that a_i = 0 & h_s = 0 where h_i = 0 --- |
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| 631 | WHERE( h_i_1d(1:npti) == 0._wp ) |
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| 632 | a_i_1d(1:npti) = 0._wp |
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| 633 | h_s_1d(1:npti) = 0._wp |
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| 634 | END WHERE |
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[8586] | 635 | ! |
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| 636 | END SUBROUTINE ice_thd_dh |
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| 637 | |
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| 638 | |
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| 639 | !!-------------------------------------------------------------------------- |
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| 640 | !! INTERFACE ice_thd_snwblow |
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[9274] | 641 | !! |
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[8586] | 642 | !! ** Purpose : Compute distribution of precip over the ice |
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[9274] | 643 | !! |
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| 644 | !! Snow accumulation in one thermodynamic time step |
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| 645 | !! snowfall is partitionned between leads and ice. |
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| 646 | !! If snow fall was uniform, a fraction (1-at_i) would fall into leads |
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| 647 | !! but because of the winds, more snow falls on leads than on sea ice |
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| 648 | !! and a greater fraction (1-at_i)^beta of the total mass of snow |
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| 649 | !! (beta < 1) falls in leads. |
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| 650 | !! In reality, beta depends on wind speed, |
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| 651 | !! and should decrease with increasing wind speed but here, it is |
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| 652 | !! considered as a constant. an average value is 0.66 |
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[8586] | 653 | !!-------------------------------------------------------------------------- |
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| 654 | !!gm I think it can be usefull to set this as a FUNCTION, not a SUBROUTINE.... |
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| 655 | SUBROUTINE ice_thd_snwblow_2d( pin, pout ) |
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| 656 | REAL(wp), DIMENSION(:,:), INTENT(in ) :: pin ! previous fraction lead ( 1. - a_i_b ) |
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| 657 | REAL(wp), DIMENSION(:,:), INTENT(inout) :: pout |
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| 658 | pout = ( 1._wp - ( pin )**rn_blow_s ) |
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| 659 | END SUBROUTINE ice_thd_snwblow_2d |
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| 660 | |
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| 661 | SUBROUTINE ice_thd_snwblow_1d( pin, pout ) |
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| 662 | REAL(wp), DIMENSION(:), INTENT(in ) :: pin |
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| 663 | REAL(wp), DIMENSION(:), INTENT(inout) :: pout |
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| 664 | pout = ( 1._wp - ( pin )**rn_blow_s ) |
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| 665 | END SUBROUTINE ice_thd_snwblow_1d |
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| 666 | |
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| 667 | #else |
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| 668 | !!---------------------------------------------------------------------- |
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[9570] | 669 | !! Default option NO SI3 sea-ice model |
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[8586] | 670 | !!---------------------------------------------------------------------- |
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| 671 | #endif |
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| 672 | |
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| 673 | !!====================================================================== |
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| 674 | END MODULE icethd_dh |
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