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update_soil.F90 @ 2889

Last change on this file since 2889 was 2888, checked in by llange, 2 years ago

PEM

Following r-2886-5, debugging some issues ( conservation of H2O, water_reservoir not initialized, info_pem which was not working)
Cleaning of some redundant routines (e.g., stopping criterion of the PEM) and variables renamed (e.g., alpha_criterion now transofrmed in ice_criterion)
Ice table subroutine is now in a module and recalled "compute_ice_table_equilibrium" (v.s. dynamic ice table, efforts ongoing)
Abort_pem introduced to avoid just stopping the pem with raw "stop" in the codes
conf_pem has been improved so that values are not hard coded (e.g., geothermal flux, mass of water_reservoir)
Regolith thermal properties updated in a cleaner way

(Not atomic commit, sorry)
LL & RV

File size: 5.0 KB

Rev	Line
[2888]	1	SUBROUTINE update_soil(ngrid,nslope,nsoil_GCM,nsoil_PEM,tendencies_waterice,waterice,p_avg_new,ice_depth,TI_PEM)
[2842]	2	#ifndef CPP_STD
[2794]	3	USE comsoil_h, only: inertiedat, volcapa
	4	USE comsoil_h_PEM, only: layer_PEM,n_1km,inertiedat_PEM
	5	USE vertical_layers_mod, ONLY: ap,bp
[2863]	6	USE comsoil_h_PEM, only: n_1km
[2794]	7	implicit none
	8	! Input:
[2888]	9	INTEGER,INTENT(IN) :: ngrid, nslope,nsoil_GCM, nsoil_PEM
[2835]	10	REAL,INTENT(IN) :: p_avg_new
[2888]	11	REAL,INTENT(IN) :: tendencies_waterice(ngrid,nslope)
[2794]	12	REAL,INTENT(IN) :: waterice(ngrid,nslope)
	13	REAL,INTENT(in) :: ice_depth(ngrid,nslope)
	14	! Outputs:
	15
	16	REAL,INTENT(INOUT) :: TI_PEM(ngrid,nsoil_PEM,nslope)
	17
	18	! Constants:
	19
	20	REAL :: inertie_thresold = 800. ! look for ice
	21	REAL :: inertie_averaged = 250 ! Mellon et al. 2000
[2849]	22	REAL :: ice_inertia = 1200 ! Inertia of ice
[2888]	23	REAL :: P610 = 610.0 ! current average pressure on Mars [Pa]
	24	REAL :: TI_breccia = 750. ! THermal inertia of Breccia following Wood 2009 [SI]
	25	REAL :: TI_bedrock = 2300. ! Thermal inertia of Bedrock following Wood 2009 [SI]
[2794]	26
	27	! Local variables:
	28
	29	INTEGER :: ig,islope,iloop,iref,k
	30	REAL :: regolith_inertia(ngrid,nslope) ! TI of the regolith
[2888]	31	REAL :: delta
	32	REAL :: TI_breccia_new
	33	! 1.Ice TI feedback
[2794]	34
[2849]	35	! do islope = 1,nslope
[2888]	36	! call soil_TIfeedback_PEM(ngrid,nsoil_PEM,waterice(:,islope), TI_PEM(:,:,islope))
[2849]	37	! enddo
[2794]	38
[2888]	39	! 2. Modification of the regolith thermal inertia.
[2794]	40
	41
	42
	43
[2888]	44	do islope = 1,nslope
	45	regolith_inertia(:,islope) = inertiedat_PEM(:,1)
	46	do ig = 1,ngrid
[2794]	47
[2888]	48	if((tendencies_waterice(ig,islope).lt.-1e-5).and.(waterice(ig,islope).eq.0)) then
	49	regolith_inertia(ig,islope) = inertie_averaged
	50	endif
	51	write(,) 'ig,islope',ig,islope,inertie_thresold,TI_PEM(ig,1,islope)
	52	if(TI_PEM(ig,1,islope).lt.inertie_thresold) then
	53	! regolith_inertia(ig,islope) = regolith_inertia(ig,islope)(p_avg_new/P610)*0.3
	54	endif
	55	TI_breccia_new = TI_breccia !(p_avg_new/P610)*0.3
	56	enddo
	57	enddo
[2794]	58
[2888]	59
	60	! 3. Build new Thermal Inertia
	61
	62	do islope=1,nslope
	63	do ig = 1,ngrid
	64	do iloop = 1,nsoil_GCM
	65	TI_PEM(ig,iloop,islope) = regolith_inertia(ig,islope)
	66	enddo
	67	if(regolith_inertia(ig,islope).lt.TI_breccia_new) then
	68	!!! transition
	69	delta = 50.
	70	TI_PEM(ig,nsoil_GCM+1,islope) = sqrt((layer_PEM(nsoil_GCM+1)-layer_PEM(nsoil_GCM))/ &
	71	(((delta-layer_PEM(nsoil_GCM))/(TI_PEM(ig,nsoil_GCM,islope)**2))+ &
	72	((layer_PEM(nsoil_GCM+1)-delta)/(TI_breccia_new**2))))
	73	do iloop=nsoil_GCM+2,n_1km
	74	TI_PEM(ig,iloop,islope) = TI_breccia_new
	75	enddo
	76	else ! we keep the high ti values
	77	do iloop=nsoil_GCM+1,n_1km
	78	TI_PEM(ig,iloop,islope) = TI_PEM(ig,nsoil_GCM,islope)
	79	enddo
	80	endif ! TI PEM and breccia comparison
	81	!! transition
	82	delta = 1000.
	83	TI_PEM(ig,n_1km+1,islope) = sqrt((layer_PEM(n_1km+1)-layer_PEM(n_1km))/ &
	84	(((delta-layer_PEM(n_1km))/(TI_PEM(ig,n_1km,islope)**2))+ &
	85	((layer_PEM(n_1km+1)-delta)/(TI_bedrock**2))))
	86	do iloop=n_1km+2,nsoil_PEM
	87	TI_PEM(ig,iloop,islope) = TI_bedrock
	88	enddo
	89	enddo ! ig
	90	ENDDO ! islope
	91
	92	! 4. Build new TI in case of ice table
[2794]	93	! a) For the regolith
	94	do ig=1,ngrid
	95	do islope=1,nslope
[2863]	96	do iloop = 1,n_1km
	97	TI_PEM(ig,iloop,islope) = TI_PEM(ig,1,islope)
	98	enddo
[2794]	99	if (ice_depth(ig,islope).gt. -1.e-10) then
	100	! 3.0 FIrst if permanent ice
	101	if (ice_depth(ig,islope).lt. 1e-10) then
	102	do iloop = 1,nsoil_PEM
	103	TI_PEM(ig,iloop,islope)=max(ice_inertia,inertiedat_PEM(ig,iloop))
	104	enddo
	105	else
	106	! 4.1 find the index of the mixed layer
	107	iref=0 ! initialize iref
	108	do k=1,nsoil_PEM ! loop on layers
	109	if (ice_depth(ig,islope).ge.layer_PEM(k)) then
	110	iref=k ! pure regolith layer up to here
	111	else
	112	! correct iref was obtained in previous cycle
	113	exit
	114	endif
	115	enddo
	116
	117	! 4.2 Build the new ti
	118	do iloop=1,iref
[2863]	119	TI_PEM(ig,iloop,islope) =TI_PEM(ig,1,islope)
[2794]	120	enddo
	121	if (iref.lt.nsoil_PEM) then
	122	if (iref.ne.0) then
	123	! mixed layer
	124	TI_PEM(ig,iref+1,islope)=sqrt((layer_PEM(iref+1)-layer_PEM(iref))/ &
	125	(((ice_depth(ig,islope)-layer_PEM(iref))/(TI_PEM(ig,iref,islope)**2))+ &
	126	((layer_PEM(iref+1)-ice_depth(ig,islope))/(ice_inertia**2))))
	127	else ! first layer is already a mixed layer
	128	! (ie: take layer(iref=0)=0)
	129	TI_PEM(ig,1,islope)=sqrt((layer_PEM(1))/ &
	130	(((ice_depth(ig,islope))/(TI_PEM(ig,1,islope)**2))+ &
	131	((layer_PEM(1)-ice_depth(ig,islope))/(ice_inertia**2))))
	132	endif ! of if (iref.ne.0)
	133	! lower layers of pure ice
	134	do iloop=iref+2,nsoil_PEM
	135	TI_PEM(ig,iloop,islope)=ice_inertia
	136	enddo
	137	endif ! of if (iref.lt.(nsoilmx))
	138	endif ! permanent glaciers
	139	endif ! depth > 0
	140	enddo !islope
	141	enddo !ig
	142
	143	!=======================================================================
	144	RETURN
[2842]	145	#endif
[2794]	146	END

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