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soil_pem_ini.F90 @ 2909

Last change on this file since 2909 was 2895, checked in by llange, 3 years ago
PEM Soil temperature initialisation has been updated Conf_PEM improved by adding some options to the users (thermal regolith depend on the pressure, depth of the subsurface layers, etc.) Minor edits then (+ svn update with RV had some issues, so there are some "artefact changes" ...) LL
File size: 3.6 KB

Rev	Line
[2895]	1	subroutine soil_pem_ini(ngrid,nsoil,therm_i,tsurf,tsoil)
	2
	3
	4	use comsoil_h_PEM, only: layer_PEM, mlayer_PEM, &
	5	mthermdiff_PEM, thermdiff_PEM, coefq_PEM, &
	6	coefd_PEM, mu_PEM,alph_PEM,beta_PEM,fluxgeo
	7	use comsoil_h,only: volcapa
	8	implicit none
	9
	10	!-----------------------------------------------------------------------
	11	! Author: LL
	12	! Purpose: Compute soil temperature using an implict 1st order scheme, stationnary solution
	13	!
	14	! Note: depths of layers and mid-layers, soil thermal inertia and
	15	! heat capacity are commons in comsoil_PEM.h
	16	!-----------------------------------------------------------------------
	17
	18	#include "dimensions.h"
	19
	20	!-----------------------------------------------------------------------
	21	! arguments
	22	! ---------
	23	! inputs:
	24	integer,intent(in) :: ngrid ! number of (horizontal) grid-points
	25	integer,intent(in) :: nsoil ! number of soil layers
	26	real,intent(in) :: therm_i(ngrid,nsoil) ! thermal inertia [SI]
	27	real,intent(in) :: tsurf(ngrid) ! surface temperature [K]
	28
	29	! outputs:
	30	real,intent(inout) :: tsoil(ngrid,nsoil) ! soil (mid-layer) temperature [K]
	31	! local variables:
	32	integer ig,ik,iloop
	33
	34	! 0. Initialisations and preprocessing step
	35
	36
	37	! 0.1 Build mthermdiff_PEM(:), the mid-layer thermal diffusivities
	38	do ig=1,ngrid
	39	do ik=0,nsoil-1
	40	mthermdiff_PEM(ig,ik)=therm_i(ig,ik+1)*therm_i(ig,ik+1)/volcapa
	41	enddo
	42	enddo
	43
	44	! 0.2 Build thermdiff(:), the "interlayer" thermal diffusivities
	45	do ig=1,ngrid
	46	do ik=1,nsoil-1
	47	thermdiff_PEM(ig,ik)=((layer_PEM(ik)-mlayer_PEM(ik-1))*mthermdiff_PEM(ig,ik) &
	48	+(mlayer_PEM(ik)-layer_PEM(ik))*mthermdiff_PEM(ig,ik-1)) &
	49	/(mlayer_PEM(ik)-mlayer_PEM(ik-1))
	50	enddo
	51	enddo
	52
	53	! 0.3 Build coefficients mu_PEM, q_{k+1/2}, d_k, alph_PEMa_k and capcal
	54	! mu_PEM
	55	mu_PEM=mlayer_PEM(0)/(mlayer_PEM(1)-mlayer_PEM(0))
	56
	57	! q_{1/2}
	58	coefq_PEM(:) = 0.
	59	! q_{k+1/2}
	60
	61	do ig=1,ngrid
	62	! d_k
	63	do ik=1,nsoil-1
	64	coefd_PEM(ig,ik)=thermdiff_PEM(ig,ik)/(mlayer_PEM(ik)-mlayer_PEM(ik-1))
	65	enddo
	66
	67	! alph_PEM_{N-1}
	68	alph_PEM(ig,nsoil-1)=coefd_PEM(ig,nsoil-1)/ &
	69	(coefq_PEM(nsoil-1)+coefd_PEM(ig,nsoil-1))
	70	! alph_PEM_k
	71	do ik=nsoil-2,1,-1
	72	alph_PEM(ig,ik)=coefd_PEM(ig,ik)/(coefq_PEM(ik)+coefd_PEM(ig,ik+1)* &
	73	(1.-alph_PEM(ig,ik+1))+coefd_PEM(ig,ik))
	74	enddo
	75
	76	enddo ! of do ig=1,ngrid
	77
	78
	79
	80	! 1. Compute beta_PEM coefficients
	81	! Bottom layer, beta_PEM_{N-1}
	82	do ig=1,ngrid
	83	beta_PEM(ig,nsoil-1)=coefq_PEM(nsoil-1)*tsoil(ig,nsoil) &
	84	/(coefq_PEM(nsoil-1)+coefd_PEM(ig,nsoil-1)) &
	85	+ fluxgeo/(coefq_PEM(nsoil-1)+coefd_PEM(ig,nsoil-1))
	86	enddo
	87	! Other layers
	88	do ik=nsoil-2,1,-1
	89	do ig=1,ngrid
	90	beta_PEM(ig,ik)=(coefq_PEM(ik)*tsoil(ig,ik+1)+ &
	91	coefd_PEM(ig,ik+1)*beta_PEM(ig,ik+1))/ &
	92	(coefq_PEM(ik)+coefd_PEM(ig,ik+1)*(1.0-alph_PEM(ig,ik+1)) &
	93	+coefd_PEM(ig,ik))
	94	enddo
	95	enddo
	96
	97	! 2. Compute soil temperatures
	98	do iloop = 1,10 !just convergence
	99	! First layer:
	100	do ig=1,ngrid
	101	tsoil(ig,1)=(tsurf(ig)+mu_PEMbeta_PEM(ig,1) &
	102	thermdiff_PEM(ig,1)/mthermdiff_PEM(ig,0))/ &
	103	(1.+mu_PEM(1.0-alph_PEM(ig,1))&
	104	thermdiff_PEM(ig,1)/mthermdiff_PEM(ig,0))
	105	! Other layers:
	106	do ik=1,nsoil-1
	107	tsoil(ig,ik+1)=alph_PEM(ig,ik)*tsoil(ig,ik)+beta_PEM(ig,ik)
	108	enddo
	109	enddo
	110
	111	enddo ! iloop
	112	end
	113

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