[3] | 1 | ! |
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| 2 | ! $Header: /home/cvsroot/LMDZ4/libf/phylmd/soil.F,v 1.1.1.1 2004/05/19 12:53:09 lmdzadmin Exp $ |
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| 3 | ! |
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| 4 | SUBROUTINE soil(ptimestep, knon, ptsrf, ptsoil, |
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| 5 | s pcapcal, pfluxgrd) |
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| 6 | |
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| 7 | c======================================================================= |
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| 8 | c |
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| 9 | c Auteur: Frederic Hourdin 30/01/92 |
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| 10 | c ------- |
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| 11 | c |
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| 12 | c objet: computation of : the soil temperature evolution |
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| 13 | c ------ the surfacic heat capacity "Capcal" |
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| 14 | c the surface conduction flux pcapcal |
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| 15 | c |
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| 16 | c |
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| 17 | c Method: implicit time integration |
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| 18 | c ------- |
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| 19 | c Consecutive ground temperatures are related by: |
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| 20 | c T(k+1) = C(k) + D(k)*T(k) (1) |
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| 21 | c the coefficients C and D are computed at the t-dt time-step. |
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| 22 | c Routine structure: |
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| 23 | c 1)new temperatures are computed using (1) |
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| 24 | c 2)C and D coefficients are computed from the new temperature |
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| 25 | c profile for the t+dt time-step |
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| 26 | c 3)the coefficients A and B are computed where the diffusive |
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| 27 | c fluxes at the t+dt time-step is given by |
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| 28 | c Fdiff = A + B Ts(t+dt) |
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| 29 | c or Fdiff = F0 + Capcal (Ts(t+dt)-Ts(t))/dt |
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| 30 | c with F0 = A + B (Ts(t)) |
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| 31 | c Capcal = B*dt |
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| 32 | c |
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| 33 | c Interface: |
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| 34 | c ---------- |
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| 35 | c |
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| 36 | c Arguments: |
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| 37 | c ---------- |
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| 38 | c ptimestep physical timestep (s) |
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| 39 | c ptsrf(klon) surface temperature at time-step t (K) |
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| 40 | c ptsoil(klon,nsoilmx) temperature inside the ground (K) |
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| 41 | c pcapcal(klon) surfacic specific heat (W*m-2*s*K-1) |
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| 42 | c pfluxgrd(klon) surface diffusive flux from ground (Wm-2) |
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| 43 | c |
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| 44 | c======================================================================= |
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| 45 | c declarations: |
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| 46 | c ------------- |
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| 47 | |
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[101] | 48 | use dimphy |
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| 49 | IMPLICIT NONE |
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[3] | 50 | #include "YOMCST.h" |
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| 51 | #include "dimsoil.h" |
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| 52 | #include "clesphys.h" |
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| 53 | |
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| 54 | c----------------------------------------------------------------------- |
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| 55 | c arguments |
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| 56 | c --------- |
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| 57 | |
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| 58 | REAL ptimestep |
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| 59 | INTEGER knon |
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| 60 | REAL ptsrf(klon),ptsoil(klon,nsoilmx) |
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| 61 | REAL pcapcal(klon),pfluxgrd(klon) |
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| 62 | |
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| 63 | c----------------------------------------------------------------------- |
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| 64 | c local arrays |
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| 65 | c ------------ |
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| 66 | |
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| 67 | INTEGER ig,jk |
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| 68 | REAL zdz2(nsoilmx),z1(klon) |
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| 69 | REAL min_period,dalph_soil |
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| 70 | REAL ztherm_i(klon) |
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| 71 | |
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| 72 | c local saved variables: |
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| 73 | c ---------------------- |
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| 74 | REAL dz1(nsoilmx),dz2(nsoilmx) |
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[101] | 75 | REAL,allocatable :: zc(:,:),zd(:,:) |
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[3] | 76 | REAL lambda |
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| 77 | SAVE dz1,dz2,zc,zd,lambda |
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| 78 | LOGICAL firstcall |
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| 79 | SAVE firstcall |
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| 80 | |
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| 81 | DATA firstcall/.true./ |
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| 82 | |
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| 83 | c----------------------------------------------------------------------- |
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| 84 | c Depthts: |
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| 85 | c -------- |
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| 86 | |
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| 87 | REAL fz,rk,fz1,rk1,rk2 |
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| 88 | fz(rk)=fz1*(dalph_soil**rk-1.)/(dalph_soil-1.) |
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| 89 | pfluxgrd(:) = 0. |
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| 90 | |
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| 91 | DO ig = 1, knon |
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| 92 | ztherm_i(ig) = inertie |
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| 93 | ENDDO |
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| 94 | |
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| 95 | IF (firstcall) THEN |
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| 96 | |
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[101] | 97 | allocate(zc(klon,nsoilmx),zd(klon,nsoilmx)) |
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| 98 | |
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[3] | 99 | c----------------------------------------------------------------------- |
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| 100 | c ground levels |
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| 101 | c grnd=z/l where l is the skin depth of the diurnal cycle: |
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| 102 | c -------------------------------------------------------- |
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| 103 | |
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| 104 | c VENUS : A REVOIR !!!! |
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| 105 | min_period=20000. ! en secondes |
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| 106 | dalph_soil=2. ! rapport entre les epaisseurs de 2 couches succ. |
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| 107 | |
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| 108 | OPEN(99,file='soil.def',status='old',form='formatted',err=9999) |
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| 109 | READ(99,*) min_period |
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| 110 | READ(99,*) dalph_soil |
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| 111 | PRINT*,'Discretization for the soil model' |
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| 112 | PRINT*,'First level e-folding depth',min_period, |
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| 113 | s ' dalph',dalph_soil |
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| 114 | CLOSE(99) |
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| 115 | 9999 CONTINUE |
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| 116 | |
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| 117 | c la premiere couche represente un dixieme de cycle diurne |
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| 118 | fz1=sqrt(min_period/3.14) |
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| 119 | |
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| 120 | DO jk=1,nsoilmx |
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| 121 | rk1=jk |
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| 122 | rk2=jk-1 |
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| 123 | dz2(jk)=fz(rk1)-fz(rk2) |
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| 124 | ENDDO |
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| 125 | DO jk=1,nsoilmx-1 |
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| 126 | rk1=jk+.5 |
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| 127 | rk2=jk-.5 |
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| 128 | dz1(jk)=1./(fz(rk1)-fz(rk2)) |
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| 129 | ENDDO |
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| 130 | lambda=fz(.5)*dz1(1) |
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| 131 | PRINT*,'full layers, intermediate layers (seconds)' |
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| 132 | DO jk=1,nsoilmx |
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| 133 | rk=jk |
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| 134 | rk1=jk+.5 |
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| 135 | rk2=jk-.5 |
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| 136 | PRINT *,'fz=', |
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| 137 | . fz(rk1)*fz(rk2)*3.14,fz(rk)*fz(rk)*3.14 |
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| 138 | ENDDO |
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| 139 | firstcall =.false. |
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| 140 | |
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| 141 | ELSE !--not firstcall |
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| 142 | c----------------------------------------------------------------------- |
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| 143 | c Computation of the soil temperatures using the Cgrd and Dgrd |
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| 144 | c coefficient computed at the previous time-step: |
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| 145 | c ----------------------------------------------- |
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| 146 | |
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| 147 | c surface temperature |
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| 148 | DO ig=1,knon |
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| 149 | ptsoil(ig,1)=(lambda*zc(ig,1)+ptsrf(ig))/ |
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| 150 | s (lambda*(1.-zd(ig,1))+1.) |
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| 151 | ENDDO |
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| 152 | |
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| 153 | c other temperatures |
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| 154 | DO jk=1,nsoilmx-1 |
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| 155 | DO ig=1,knon |
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| 156 | ptsoil(ig,jk+1)=zc(ig,jk)+zd(ig,jk)*ptsoil(ig,jk) |
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| 157 | ENDDO |
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| 158 | ENDDO |
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| 159 | |
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| 160 | ENDIF !--not firstcall |
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| 161 | c----------------------------------------------------------------------- |
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| 162 | c Computation of the Cgrd and Dgrd coefficient for the next step: |
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| 163 | c --------------------------------------------------------------- |
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| 164 | |
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| 165 | DO jk=1,nsoilmx |
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| 166 | zdz2(jk)=dz2(jk)/ptimestep |
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| 167 | ENDDO |
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| 168 | |
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| 169 | DO ig=1,knon |
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| 170 | z1(ig)=zdz2(nsoilmx)+dz1(nsoilmx-1) |
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| 171 | zc(ig,nsoilmx-1)= |
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| 172 | $ zdz2(nsoilmx)*ptsoil(ig,nsoilmx)/z1(ig) |
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| 173 | zd(ig,nsoilmx-1)=dz1(nsoilmx-1)/z1(ig) |
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| 174 | ENDDO |
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| 175 | |
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| 176 | DO jk=nsoilmx-1,2,-1 |
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| 177 | DO ig=1,knon |
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| 178 | z1(ig)=1./(zdz2(jk)+dz1(jk-1)+dz1(jk) |
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| 179 | $ *(1.-zd(ig,jk))) |
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| 180 | zc(ig,jk-1)= |
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| 181 | s (ptsoil(ig,jk)*zdz2(jk)+dz1(jk)*zc(ig,jk)) |
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| 182 | $ *z1(ig) |
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| 183 | zd(ig,jk-1)=dz1(jk-1)*z1(ig) |
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| 184 | ENDDO |
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| 185 | ENDDO |
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| 186 | |
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| 187 | c----------------------------------------------------------------------- |
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| 188 | c computation of the surface diffusive flux from ground and |
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| 189 | c calorific capacity of the ground: |
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| 190 | c --------------------------------- |
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| 191 | |
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| 192 | DO ig=1,knon |
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| 193 | pfluxgrd(ig)=ztherm_i(ig)*dz1(1)* |
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| 194 | s (zc(ig,1)+(zd(ig,1)-1.)*ptsoil(ig,1)) |
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| 195 | pcapcal(ig)=ztherm_i(ig)* |
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| 196 | s (dz2(1)+ptimestep*(1.-zd(ig,1))*dz1(1)) |
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| 197 | z1(ig)=lambda*(1.-zd(ig,1))+1. |
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| 198 | pcapcal(ig)=pcapcal(ig)/z1(ig) |
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| 199 | pfluxgrd(ig) = pfluxgrd(ig) |
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| 200 | s + pcapcal(ig) * (ptsoil(ig,1) * z1(ig) |
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| 201 | $ - lambda * zc(ig,1) |
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| 202 | $ - ptsrf(ig)) |
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| 203 | s /ptimestep |
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| 204 | ENDDO |
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| 205 | |
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| 206 | RETURN |
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| 207 | END |
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