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soil.F @ 1268

Last change on this file since 1268 was 1268, checked in by aslmd, 11 years ago
LMDZ.MARS. related to r1266. forgot to remove a few now-obsolete dimensions.h includes in Mars physics.
File size: 5.6 KB

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1	subroutine soil(ngrid,nsoil,firstcall,
2	& therm_i,
3	& timestep,tsurf,tsoil,
4	& capcal,fluxgrd)
5
6	use comsoil_h, only: layer, mlayer, volcapa,
7	& mthermdiff, thermdiff, coefq,
8	& coefd, alph, beta, mu
9	use surfdat_h, only: watercaptag, inert_h2o_ice
10
11	implicit none
12
13	!-----------------------------------------------------------------------
14	! Author: Ehouarn Millour
15	!
16	! Purpose: Compute soil temperature using an implict 1st order scheme
17	!
18	! Note: depths of layers and mid-layers, soil thermal inertia and
19	! heat capacity are commons in comsoil_h
20	!-----------------------------------------------------------------------
21
22	#include "callkeys.h"
23
24	c-----------------------------------------------------------------------
25	! arguments
26	! ---------
27	! inputs:
28	integer ngrid ! number of (horizontal) grid-points
29	integer nsoil ! number of soil layers
30	logical firstcall ! identifier for initialization call
31	real therm_i(ngrid,nsoil) ! thermal inertia
32	real timestep ! time step
33	real tsurf(ngrid) ! surface temperature
34	! outputs:
35	real tsoil(ngrid,nsoil) ! soil (mid-layer) temperature
36	real capcal(ngrid) ! surface specific heat
37	real fluxgrd(ngrid) ! surface diffusive heat flux
38
39	! local variables:
40	integer ig,ik
41
42	! 0. Initialisations and preprocessing step
43	if (firstcall.or.tifeedback) then
44	! note: firstcall is set to .true. or .false. by the caller
45	! and not changed by soil.F
46	! 0.1 Build mthermdiff(:), the mid-layer thermal diffusivities
47	do ig=1,ngrid
48	if (watercaptag(ig)) then
49	do ik=0,nsoil-1
50	! If we have permanent ice, we use the water ice thermal inertia from ground to last layer.
51	mthermdiff(ig,ik)=inert_h2o_ice*inert_h2o_ice/volcapa
52	enddo
53	else
54	do ik=0,nsoil-1
55	mthermdiff(ig,ik)=therm_i(ig,ik+1)*therm_i(ig,ik+1)/volcapa
56	enddo
57	endif
58	enddo
59
60	#ifdef MESOSCALE
61	do ig=1,ngrid
62	if ( therm_i(ig,1) .ge. inert_h2o_ice ) then
63	print *, "limit max TI ", therm_i(ig,1), inert_h2o_ice
64	do ik=0,nsoil-1
65	mthermdiff(ig,ik)=inert_h2o_ice*inert_h2o_ice/volcapa
66	enddo
67	endif
68	enddo
69	#endif
70
71	! 0.2 Build thermdiff(:), the "interlayer" thermal diffusivities
72	do ig=1,ngrid
73	do ik=1,nsoil-1
74	thermdiff(ig,ik)=((layer(ik)-mlayer(ik-1))*mthermdiff(ig,ik)
75	& +(mlayer(ik)-layer(ik))*mthermdiff(ig,ik-1))
76	& /(mlayer(ik)-mlayer(ik-1))
77	! write(,),'soil: ik: ',ik,' thermdiff:',thermdiff(ig,ik)
78	enddo
79	enddo
80
81	! 0.3 Build coefficients mu, q_{k+1/2}, d_k, alpha_k and capcal
82	! mu
83	mu=mlayer(0)/(mlayer(1)-mlayer(0))
84
85	! q_{1/2}
86	coefq(0)=volcapa*layer(1)/timestep
87	! q_{k+1/2}
88	do ik=1,nsoil-1
89	coefq(ik)=volcapa*(layer(ik+1)-layer(ik))
90	& /timestep
91	enddo
92
93	do ig=1,ngrid
94	! d_k
95	do ik=1,nsoil-1
96	coefd(ig,ik)=thermdiff(ig,ik)/(mlayer(ik)-mlayer(ik-1))
97	enddo
98
99	! alph_{N-1}
100	alph(ig,nsoil-1)=coefd(ig,nsoil-1)/
101	& (coefq(nsoil-1)+coefd(ig,nsoil-1))
102	! alph_k
103	do ik=nsoil-2,1,-1
104	alph(ig,ik)=coefd(ig,ik)/(coefq(ik)+coefd(ig,ik+1)*
105	& (1.-alph(ig,ik+1))+coefd(ig,ik))
106	enddo
107
108	! capcal
109	! Cstar
110	capcal(ig)=volcapa*layer(1)+
111	& (thermdiff(ig,1)/(mlayer(1)-mlayer(0)))*
112	& (timestep*(1.-alph(ig,1)))
113	! Cs
114	capcal(ig)=capcal(ig)/(1.+mu(1.0-alph(ig,1))
115	& thermdiff(ig,1)/mthermdiff(ig,0))
116	! write(,)'soil: ig=',ig,' capcal(ig)=',capcal(ig)
117	enddo ! of do ig=1,ngrid
118
119	endif ! of if (firstcall.or.tifeedback)
120
121	! 1. Compute soil temperatures
122	IF (.not.firstcall) THEN
123	! First layer:
124	do ig=1,ngrid
125	tsoil(ig,1)=(tsurf(ig)+mubeta(ig,1)
126	& thermdiff(ig,1)/mthermdiff(ig,0))/
127	& (1.+mu(1.0-alph(ig,1))
128	& thermdiff(ig,1)/mthermdiff(ig,0))
129	enddo
130	! Other layers:
131	do ik=1,nsoil-1
132	do ig=1,ngrid
133	tsoil(ig,ik+1)=alph(ig,ik)*tsoil(ig,ik)+beta(ig,ik)
134	enddo
135	enddo
136
137	ENDIF! of if (.not.firstcall)
138
139	! 2. Compute beta coefficients (preprocessing for next time step)
140	! Bottom layer, beta_{N-1}
141	do ig=1,ngrid
142	beta(ig,nsoil-1)=coefq(nsoil-1)*tsoil(ig,nsoil)
143	& /(coefq(nsoil-1)+coefd(ig,nsoil-1))
144	enddo
145	! Other layers
146	do ik=nsoil-2,1,-1
147	do ig=1,ngrid
148	beta(ig,ik)=(coefq(ik)*tsoil(ig,ik+1)+
149	& coefd(ig,ik+1)*beta(ig,ik+1))/
150	& (coefq(ik)+coefd(ig,ik+1)*(1.0-alph(ig,ik+1))
151	& +coefd(ig,ik))
152	enddo
153	enddo
154
155	! 3. Compute surface diffusive flux & calorific capacity
156	do ig=1,ngrid
157	! Cstar
158	! capcal(ig)=volcapa(ig,1)*layer(ig,1)+
159	! & (thermdiff(ig,1)/(mlayer(ig,1)-mlayer(ig,0)))*
160	! & (timestep*(1.-alph(ig,1)))
161	! Fstar
162	fluxgrd(ig)=(thermdiff(ig,1)/(mlayer(1)-mlayer(0)))*
163	& (beta(ig,1)+(alph(ig,1)-1.0)*tsoil(ig,1))
164
165	! mu=mlayer(ig,0)/(mlayer(ig,1)-mlayer(ig,0))
166	! capcal(ig)=capcal(ig)/(1.+mu(1.0-alph(ig,1))
167	! & thermdiff(ig,1)/mthermdiff(ig,0))
168	! Fs
169	fluxgrd(ig)=fluxgrd(ig)+(capcal(ig)/timestep)*
170	& (tsoil(ig,1)(1.+mu(1.0-alph(ig,1))*
171	& thermdiff(ig,1)/mthermdiff(ig,0))
172	& -tsurf(ig)-mubeta(ig,1)
173	& thermdiff(ig,1)/mthermdiff(ig,0))
174	enddo
175
176	end
177

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