[996] | 1 | ! |
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| 2 | ! $Header$ |
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| 3 | ! |
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[3974] | 4 | SUBROUTINE soil(ptimestep, indice, knon, snow, ptsrf, qsol, & |
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| 5 | lon, lat, ptsoil, pcapcal, pfluxgrd) |
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[996] | 6 | |
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[5274] | 7 | USE yomcst_mod_h, ONLY: RPI, RCLUM, RHPLA, RKBOL, RNAVO & |
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| 8 | , RDAY, REA, REPSM, RSIYEA, RSIDAY, ROMEGA & |
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| 9 | , R_ecc, R_peri, R_incl & |
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| 10 | , RA, RG, R1SA & |
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| 11 | , RSIGMA & |
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| 12 | , R, RMD, RMV, RD, RV, RCPD & |
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| 13 | , RMO3, RMCO2, RMC, RMCH4, RMN2O, RMCFC11, RMCFC12 & |
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| 14 | , RCPV, RCVD, RCVV, RKAPPA, RETV, eps_w & |
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| 15 | , RCW, RCS & |
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| 16 | , RLVTT, RLSTT, RLMLT, RTT, RATM & |
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| 17 | , RESTT, RALPW, RBETW, RGAMW, RALPS, RBETS, RGAMS & |
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| 18 | , RALPD, RBETD, RGAMD |
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[996] | 19 | USE dimphy |
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| 20 | USE mod_phys_lmdz_para |
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[1785] | 21 | USE indice_sol_mod |
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[2311] | 22 | USE print_control_mod, ONLY: lunout |
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[5273] | 23 | USE dimsoil_mod_h, ONLY: nsoilmx |
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[1785] | 24 | |
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[996] | 25 | IMPLICIT NONE |
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| 26 | |
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| 27 | !======================================================================= |
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| 28 | ! |
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| 29 | ! Auteur: Frederic Hourdin 30/01/92 |
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| 30 | ! ------- |
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| 31 | ! |
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| 32 | ! Object: Computation of : the soil temperature evolution |
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| 33 | ! ------- the surfacic heat capacity "Capcal" |
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| 34 | ! the surface conduction flux pcapcal |
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| 35 | ! |
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[3974] | 36 | ! Update: 2021/07 : soil thermal inertia, formerly a constant value, |
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| 37 | ! ------ can also be now a function of soil moisture (F Cheruy's idea) |
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| 38 | ! depending on iflag_inertie, read from physiq.def via conf_phys_m.F90 |
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| 39 | ! ("Stage L3" Eve Rebouillat, with E Vignon, A Sima, F Cheruy) |
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[996] | 40 | ! |
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| 41 | ! Method: Implicit time integration |
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| 42 | ! ------- |
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| 43 | ! Consecutive ground temperatures are related by: |
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| 44 | ! T(k+1) = C(k) + D(k)*T(k) (*) |
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| 45 | ! The coefficients C and D are computed at the t-dt time-step. |
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| 46 | ! Routine structure: |
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| 47 | ! 1) C and D coefficients are computed from the old temperature |
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| 48 | ! 2) new temperatures are computed using (*) |
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| 49 | ! 3) C and D coefficients are computed from the new temperature |
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| 50 | ! profile for the t+dt time-step |
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| 51 | ! 4) the coefficients A and B are computed where the diffusive |
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| 52 | ! fluxes at the t+dt time-step is given by |
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| 53 | ! Fdiff = A + B Ts(t+dt) |
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| 54 | ! or Fdiff = F0 + Capcal (Ts(t+dt)-Ts(t))/dt |
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| 55 | ! with F0 = A + B (Ts(t)) |
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| 56 | ! Capcal = B*dt |
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[5274] | 57 | ! |
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[996] | 58 | ! Interface: |
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| 59 | ! ---------- |
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| 60 | ! |
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| 61 | ! Arguments: |
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| 62 | ! ---------- |
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| 63 | ! ptimestep physical timestep (s) |
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| 64 | ! indice sub-surface index |
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| 65 | ! snow(klon) snow |
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| 66 | ! ptsrf(klon) surface temperature at time-step t (K) |
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[3974] | 67 | ! qsol(klon) soil moisture (kg/m2 or mm) |
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| 68 | ! lon(klon) longitude in radian |
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| 69 | ! lat(klon) latitude in radian |
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[996] | 70 | ! ptsoil(klon,nsoilmx) temperature inside the ground (K) |
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| 71 | ! pcapcal(klon) surfacic specific heat (W*m-2*s*K-1) |
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| 72 | ! pfluxgrd(klon) surface diffusive flux from ground (Wm-2) |
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[5274] | 73 | ! |
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[996] | 74 | !======================================================================= |
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| 75 | INCLUDE "comsoil.h" |
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| 76 | !----------------------------------------------------------------------- |
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| 77 | ! Arguments |
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| 78 | ! --------- |
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| 79 | REAL, INTENT(IN) :: ptimestep |
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[3974] | 80 | INTEGER, INTENT(IN) :: indice, knon !, knindex |
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[996] | 81 | REAL, DIMENSION(klon), INTENT(IN) :: snow |
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| 82 | REAL, DIMENSION(klon), INTENT(IN) :: ptsrf |
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[3974] | 83 | REAL, DIMENSION(klon), INTENT(IN) :: qsol |
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| 84 | REAL, DIMENSION(klon), INTENT(IN) :: lon |
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| 85 | REAL, DIMENSION(klon), INTENT(IN) :: lat |
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| 86 | |
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[996] | 87 | REAL, DIMENSION(klon,nsoilmx), INTENT(INOUT) :: ptsoil |
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| 88 | REAL, DIMENSION(klon), INTENT(OUT) :: pcapcal |
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| 89 | REAL, DIMENSION(klon), INTENT(OUT) :: pfluxgrd |
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| 90 | |
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| 91 | !----------------------------------------------------------------------- |
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| 92 | ! Local variables |
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| 93 | ! --------------- |
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| 94 | INTEGER :: ig, jk, ierr |
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| 95 | REAL :: min_period,dalph_soil |
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| 96 | REAL, DIMENSION(nsoilmx) :: zdz2 |
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| 97 | REAL :: z1s |
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| 98 | REAL, DIMENSION(klon) :: ztherm_i |
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| 99 | REAL, DIMENSION(klon,nsoilmx,nbsrf) :: C_coef, D_coef |
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| 100 | |
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| 101 | ! Local saved variables |
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| 102 | ! --------------------- |
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| 103 | REAL, SAVE :: lambda |
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| 104 | !$OMP THREADPRIVATE(lambda) |
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| 105 | REAL, DIMENSION(nsoilmx), SAVE :: dz1, dz2 |
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| 106 | !$OMP THREADPRIVATE(dz1,dz2) |
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| 107 | LOGICAL, SAVE :: firstcall=.TRUE. |
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| 108 | !$OMP THREADPRIVATE(firstcall) |
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| 109 | |
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| 110 | !----------------------------------------------------------------------- |
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| 111 | ! Depthts: |
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| 112 | ! -------- |
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| 113 | REAL fz,rk,fz1,rk1,rk2 |
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| 114 | fz(rk)=fz1*(dalph_soil**rk-1.)/(dalph_soil-1.) |
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| 115 | |
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| 116 | |
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| 117 | !----------------------------------------------------------------------- |
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| 118 | ! Calculation of some constants |
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| 119 | ! NB! These constants do not depend on the sub-surfaces |
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| 120 | !----------------------------------------------------------------------- |
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| 121 | |
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| 122 | IF (firstcall) THEN |
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| 123 | !----------------------------------------------------------------------- |
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| 124 | ! ground levels |
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| 125 | ! grnd=z/l where l is the skin depth of the diurnal cycle: |
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| 126 | !----------------------------------------------------------------------- |
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| 127 | |
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| 128 | min_period=1800. ! en secondes |
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| 129 | dalph_soil=2. ! rapport entre les epaisseurs de 2 couches succ. |
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| 130 | !$OMP MASTER |
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| 131 | IF (is_mpi_root) THEN |
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| 132 | OPEN(99,file='soil.def',status='old',form='formatted',iostat=ierr) |
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| 133 | IF (ierr == 0) THEN ! Read file only if it exists |
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| 134 | READ(99,*) min_period |
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| 135 | READ(99,*) dalph_soil |
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[1575] | 136 | WRITE(lunout,*)'Discretization for the soil model' |
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| 137 | WRITE(lunout,*)'First level e-folding depth',min_period, & |
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[996] | 138 | ' dalph',dalph_soil |
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| 139 | CLOSE(99) |
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| 140 | END IF |
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| 141 | ENDIF |
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| 142 | !$OMP END MASTER |
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| 143 | CALL bcast(min_period) |
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| 144 | CALL bcast(dalph_soil) |
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| 145 | |
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| 146 | ! la premiere couche represente un dixieme de cycle diurne |
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| 147 | fz1=SQRT(min_period/3.14) |
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| 148 | |
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| 149 | DO jk=1,nsoilmx |
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| 150 | rk1=jk |
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| 151 | rk2=jk-1 |
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| 152 | dz2(jk)=fz(rk1)-fz(rk2) |
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| 153 | ENDDO |
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| 154 | DO jk=1,nsoilmx-1 |
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| 155 | rk1=jk+.5 |
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| 156 | rk2=jk-.5 |
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| 157 | dz1(jk)=1./(fz(rk1)-fz(rk2)) |
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| 158 | ENDDO |
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| 159 | lambda=fz(.5)*dz1(1) |
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[1575] | 160 | WRITE(lunout,*)'full layers, intermediate layers (seconds)' |
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[996] | 161 | DO jk=1,nsoilmx |
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| 162 | rk=jk |
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| 163 | rk1=jk+.5 |
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| 164 | rk2=jk-.5 |
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[1575] | 165 | WRITE(lunout,*)'fz=', & |
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[996] | 166 | fz(rk1)*fz(rk2)*3.14,fz(rk)*fz(rk)*3.14 |
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| 167 | ENDDO |
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| 168 | |
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| 169 | firstcall =.FALSE. |
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| 170 | END IF |
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| 171 | |
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| 172 | |
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| 173 | !----------------------------------------------------------------------- |
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| 174 | ! Calcul de l'inertie thermique a partir de la variable rnat. |
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[2915] | 175 | ! on initialise a inertie_sic meme au-dessus d'un point de mer au cas |
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[996] | 176 | ! ou le point de mer devienne point de glace au pas suivant |
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| 177 | ! on corrige si on a un point de terre avec ou sans glace |
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| 178 | ! |
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[2915] | 179 | ! iophys can be used to write the ztherm_i variable in a phys.nc file |
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| 180 | ! and check the results; to do so, add "CALL iophys_ini" in physiq_mod |
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| 181 | ! and add knindex to the list of inputs in all the calls to soil.F90 |
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| 182 | ! (and to soil.F90 itself !) |
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[996] | 183 | !----------------------------------------------------------------------- |
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[2915] | 184 | |
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[996] | 185 | IF (indice == is_sic) THEN |
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| 186 | DO ig = 1, knon |
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[2915] | 187 | ztherm_i(ig) = inertie_sic |
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[996] | 188 | ENDDO |
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[2915] | 189 | IF (iflag_sic == 0) THEN |
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| 190 | DO ig = 1, knon |
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| 191 | IF (snow(ig) > 0.0) ztherm_i(ig) = inertie_sno |
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| 192 | ENDDO |
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| 193 | ! Otherwise sea-ice keeps the same inertia, even when covered by snow |
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| 194 | ENDIF |
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| 195 | ! CALL iophys_ecrit_index('ztherm_sic', 1, 'ztherm_sic', 'USI', & |
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| 196 | ! knon, knindex, ztherm_i) |
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[996] | 197 | ELSE IF (indice == is_lic) THEN |
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| 198 | DO ig = 1, knon |
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[2915] | 199 | ztherm_i(ig) = inertie_lic |
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[996] | 200 | IF (snow(ig) > 0.0) ztherm_i(ig) = inertie_sno |
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| 201 | ENDDO |
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[2915] | 202 | ! CALL iophys_ecrit_index('ztherm_lic', 1, 'ztherm_lic', 'USI', & |
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| 203 | ! knon, knindex, ztherm_i) |
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[996] | 204 | ELSE IF (indice == is_ter) THEN |
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[3974] | 205 | ! |
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| 206 | ! La relation entre l'inertie thermique du sol et qsol change d'apres |
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| 207 | ! iflag_inertie, defini dans physiq.def, et appele via comsoil.h |
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| 208 | ! |
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[996] | 209 | DO ig = 1, knon |
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[3974] | 210 | ! iflag_inertie=0 correspond au cas inertie=constant, comme avant |
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| 211 | IF (iflag_inertie==0) THEN |
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| 212 | ztherm_i(ig) = inertie_sol |
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| 213 | ELSE IF (iflag_inertie == 1) THEN |
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| 214 | ! I = a_qsol * qsol + b modele lineaire deduit d'une |
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| 215 | ! regression lineaire I = a_mrsos * mrsos + b obtenue sur |
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| 216 | ! sorties MO d'une simulation LMDZOR(CMIP6) sur l'annee 2000 |
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| 217 | ! sur tous les points avec frac_snow=0 |
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| 218 | ! Difference entre qsol et mrsos prise en compte par un |
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| 219 | ! facteur d'echelle sur le coefficient directeur de regression: |
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| 220 | ! fact = 35./150. = mrsos_max/qsol_max |
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| 221 | ! et a_qsol = a_mrsos * fact (car a = dI/dHumidite) |
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| 222 | ztherm_i(ig) = 30.0 *35.0/150.0 *qsol(ig) +770.0 |
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| 223 | ! AS : pour qsol entre 0 - 150, on a I entre 770 - 1820 |
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| 224 | ELSE IF (iflag_inertie == 2) THEN |
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| 225 | ! deux regressions lineaires, sur les memes sorties, |
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| 226 | ! distinguant le type de sol : sable ou autre (limons/argile) |
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| 227 | ! Implementation simple : regression type "sable" seulement pour |
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| 228 | ! Sahara, defini par une "boite" lat/lon (NB : en radians !! ) |
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| 229 | IF (lon(ig)>-0.35 .AND. lon(ig)<0.70 .AND. lat(ig)>0.17 .AND. lat(ig)<0.52) THEN |
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| 230 | ! Valeurs theoriquement entre 728 et 2373 ; qsol valeurs basses |
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| 231 | ztherm_i(ig) = 47. *35.0/150.0 *qsol(ig) +728. ! boite type "sable" pour Sahara |
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| 232 | ELSE |
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| 233 | ! Valeurs theoriquement entre 550 et 1940 ; qsol valeurs moyennes et hautes |
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| 234 | ztherm_i(ig) = 41. *35.0/150.0 *qsol(ig) +505. |
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| 235 | ENDIF |
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| 236 | ELSE IF (iflag_inertie == 3) THEN |
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| 237 | ! AS : idee a tester : |
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| 238 | ! si la relation doit etre une droite, |
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| 239 | ! definissons-la en fonction des valeurs min et max de qsol (0:150), |
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| 240 | ! et de l'inertie (900 : 2000 ou 2400 ; choix ici: 2000) |
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| 241 | ! I = I_min + qsol * (I_max - I_min)/(qsol_max - qsol_min) |
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| 242 | ztherm_i(ig) = 900. + qsol(ig) * (2000. - 900.)/150. |
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| 243 | ELSE |
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| 244 | WRITE (lunout,*) "Le choix iflag_inertie = ",iflag_inertie," n'est pas defini. Veuillez choisir un entier entre 0 et 3" |
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| 245 | ENDIF |
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| 246 | ! |
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| 247 | ! Fin de l'introduction de la relation entre l'inertie thermique du sol et qsol |
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| 248 | !------------------------------------------- |
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| 249 | !AS : donc le moindre flocon de neige sur un point de grid |
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| 250 | ! fait que l'inertie du point passe a la valeur pour neige ! |
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[996] | 251 | IF (snow(ig) > 0.0) ztherm_i(ig) = inertie_sno |
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[3974] | 252 | |
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[996] | 253 | ENDDO |
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[2915] | 254 | ! CALL iophys_ecrit_index('ztherm_ter', 1, 'ztherm_ter', 'USI', & |
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| 255 | ! knon, knindex, ztherm_i) |
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[996] | 256 | ELSE IF (indice == is_oce) THEN |
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| 257 | DO ig = 1, knon |
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[2915] | 258 | ! This is just in case, but SST should be used by the model anyway |
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| 259 | ztherm_i(ig) = inertie_sic |
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[996] | 260 | ENDDO |
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[2915] | 261 | ! CALL iophys_ecrit_index('ztherm_oce', 1, 'ztherm_oce', 'USI', & |
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| 262 | ! knon, knindex, ztherm_i) |
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[996] | 263 | ELSE |
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[1575] | 264 | WRITE(lunout,*) "valeur d indice non prevue", indice |
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[2311] | 265 | call abort_physic("soil", "", 1) |
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[996] | 266 | ENDIF |
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| 267 | |
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| 268 | |
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| 269 | !----------------------------------------------------------------------- |
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| 270 | ! 1) |
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| 271 | ! Calculation of Cgrf and Dgrd coefficients using soil temperature from |
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| 272 | ! previous time step. |
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| 273 | ! |
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| 274 | ! These variables are recalculated on the local compressed grid instead |
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| 275 | ! of saved in restart file. |
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| 276 | !----------------------------------------------------------------------- |
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| 277 | DO jk=1,nsoilmx |
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| 278 | zdz2(jk)=dz2(jk)/ptimestep |
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| 279 | ENDDO |
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| 280 | |
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| 281 | DO ig=1,knon |
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| 282 | z1s = zdz2(nsoilmx)+dz1(nsoilmx-1) |
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| 283 | C_coef(ig,nsoilmx-1,indice)= & |
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| 284 | zdz2(nsoilmx)*ptsoil(ig,nsoilmx)/z1s |
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| 285 | D_coef(ig,nsoilmx-1,indice)=dz1(nsoilmx-1)/z1s |
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| 286 | ENDDO |
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| 287 | |
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| 288 | DO jk=nsoilmx-1,2,-1 |
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| 289 | DO ig=1,knon |
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| 290 | z1s = 1./(zdz2(jk)+dz1(jk-1)+dz1(jk) & |
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| 291 | *(1.-D_coef(ig,jk,indice))) |
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| 292 | C_coef(ig,jk-1,indice)= & |
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| 293 | (ptsoil(ig,jk)*zdz2(jk)+dz1(jk)*C_coef(ig,jk,indice)) * z1s |
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| 294 | D_coef(ig,jk-1,indice)=dz1(jk-1)*z1s |
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| 295 | ENDDO |
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| 296 | ENDDO |
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| 297 | |
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| 298 | !----------------------------------------------------------------------- |
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| 299 | ! 2) |
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| 300 | ! Computation of the soil temperatures using the Cgrd and Dgrd |
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| 301 | ! coefficient computed above |
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| 302 | ! |
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| 303 | !----------------------------------------------------------------------- |
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| 304 | |
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| 305 | ! Surface temperature |
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| 306 | DO ig=1,knon |
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| 307 | ptsoil(ig,1)=(lambda*C_coef(ig,1,indice)+ptsrf(ig))/ & |
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| 308 | (lambda*(1.-D_coef(ig,1,indice))+1.) |
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| 309 | ENDDO |
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| 310 | |
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| 311 | ! Other temperatures |
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| 312 | DO jk=1,nsoilmx-1 |
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| 313 | DO ig=1,knon |
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| 314 | ptsoil(ig,jk+1)=C_coef(ig,jk,indice)+D_coef(ig,jk,indice) & |
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| 315 | *ptsoil(ig,jk) |
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| 316 | ENDDO |
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| 317 | ENDDO |
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| 318 | |
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| 319 | IF (indice == is_sic) THEN |
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| 320 | DO ig = 1 , knon |
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| 321 | ptsoil(ig,nsoilmx) = RTT - 1.8 |
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| 322 | END DO |
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| 323 | ENDIF |
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| 324 | |
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| 325 | !----------------------------------------------------------------------- |
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| 326 | ! 3) |
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| 327 | ! Calculate the Cgrd and Dgrd coefficient corresponding to actual soil |
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| 328 | ! temperature |
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| 329 | !----------------------------------------------------------------------- |
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| 330 | DO ig=1,knon |
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| 331 | z1s = zdz2(nsoilmx)+dz1(nsoilmx-1) |
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| 332 | C_coef(ig,nsoilmx-1,indice) = zdz2(nsoilmx)*ptsoil(ig,nsoilmx)/z1s |
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| 333 | D_coef(ig,nsoilmx-1,indice) = dz1(nsoilmx-1)/z1s |
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| 334 | ENDDO |
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| 335 | |
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| 336 | DO jk=nsoilmx-1,2,-1 |
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| 337 | DO ig=1,knon |
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| 338 | z1s = 1./(zdz2(jk)+dz1(jk-1)+dz1(jk) & |
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| 339 | *(1.-D_coef(ig,jk,indice))) |
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| 340 | C_coef(ig,jk-1,indice) = & |
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| 341 | (ptsoil(ig,jk)*zdz2(jk)+dz1(jk)*C_coef(ig,jk,indice)) * z1s |
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| 342 | D_coef(ig,jk-1,indice) = dz1(jk-1)*z1s |
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| 343 | ENDDO |
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| 344 | ENDDO |
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| 345 | |
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| 346 | !----------------------------------------------------------------------- |
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| 347 | ! 4) |
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| 348 | ! Computation of the surface diffusive flux from ground and |
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| 349 | ! calorific capacity of the ground |
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| 350 | !----------------------------------------------------------------------- |
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| 351 | DO ig=1,knon |
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| 352 | pfluxgrd(ig) = ztherm_i(ig)*dz1(1)* & |
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| 353 | (C_coef(ig,1,indice)+(D_coef(ig,1,indice)-1.)*ptsoil(ig,1)) |
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| 354 | pcapcal(ig) = ztherm_i(ig)* & |
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| 355 | (dz2(1)+ptimestep*(1.-D_coef(ig,1,indice))*dz1(1)) |
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| 356 | z1s = lambda*(1.-D_coef(ig,1,indice))+1. |
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| 357 | pcapcal(ig) = pcapcal(ig)/z1s |
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| 358 | pfluxgrd(ig) = pfluxgrd(ig) & |
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| 359 | + pcapcal(ig) * (ptsoil(ig,1) * z1s & |
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| 360 | - lambda * C_coef(ig,1,indice) & |
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| 361 | - ptsrf(ig)) & |
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| 362 | /ptimestep |
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| 363 | ENDDO |
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| 364 | |
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| 365 | END SUBROUTINE soil |
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