pkg/seaice/seaice_tracer_phys.F

C $Header: /u/gcmpack/MITgcm/pkg/seaice/seaice_tracer_phys.F,v 1.9 2012/12/27 23:05:47 gforget Exp $
C $Name:  $

#include "SEAICE_OPTIONS.h"

CStartOfInterface
      SUBROUTINE SEAICE_TRACER_PHYS( myTime, myIter, myThid )
C     *=======================================================*
C     | SUBROUTINE seaice_tracer_phys
C     | o Time step SItr/SItrEFF as a result of
C     |   seaice thermodynamics and specific tracer physics
C     *=======================================================*
      IMPLICIT NONE

C     === Global variables ===
#include "SIZE.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "FFIELDS.h"
#include "DYNVARS.h"
#include "SEAICE_SIZE.h"
#include "SEAICE.h"
#include "SEAICE_PARAMS.h"
#include "SEAICE_TRACER.h"
#ifdef ALLOW_SALT_PLUME
# include "SALT_PLUME.h"
#endif

C     === Routine arguments ===
C     INPUT:
C     myTime  :: Simulation time
C     myIter  :: Simulation timestep number
C     myThid  :: Thread no. that called this routine.
C     OUTPUT:
      _RL myTime
      INTEGER myIter, myThid
CEndOfInterface

C     === Local variables ===
#ifdef ALLOW_SITRACER

      INTEGER iTr, jTh, I, J, bi, bj, ks
      _RL SItrFromOcean  (1:sNx,1:sNy)
      _RL SItrFromFlood   (1:sNx,1:sNy)
      _RL HEFFprev, HEFFpost, growFact, meltPart, tmpscal1
      _RL SItrExpand  (1:sNx,1:sNy)
      _RL AREAprev, AREApost, expandFact
      CHARACTER*8   diagName

#ifdef ALLOW_SITRACER_DEBUG_DIAG
      _RL DIAGarray     (1:sNx,1:sNy,Nr)
#endif

cgf for now I do not fully account for ocean-ice fluxes of tracer
cgf -> I just prescribe it consistent with age tracer
cgf eventually I will need to handle them as function params

      ks=1

      DO bj=myByLo(myThid),myByHi(myThid)
      DO bi=myBxLo(myThid),myBxHi(myThid)
      DO iTr=1,SItrNumInUse

c 0) set ice-ocean and ice-snow exchange values
c =============================================
      DO J=1,sNy
       DO I=1,sNx
        SItrFromOcean(i,j)=SItrFromOcean0(iTr)
        SItrFromFlood(i,j)=SItrFromFlood0(iTr)
        SItrExpand(i,j)=SItrExpand0(iTr)
       ENDDO
      ENDDO
c salinity tracer:
      if ( (SItrName(iTr).EQ.'salinity').AND.
     &      (SItrFromOceanFrac(iTr).GT.ZERO) ) then
       DO J=1,sNy
        DO I=1,sNx
         SItrFromOcean(i,j)=SItrFromOceanFrac(iTr)*salt(I,j,ks,bi,bj)
         SItrFromFlood(i,j)=SItrFromFloodFrac(iTr)*salt(I,j,ks,bi,bj)
        ENDDO
       ENDDO
      endif
c 1) seaice thermodynamics processes
c ==================================
      if (SItrMate(iTr).EQ.'HEFF') then
      DO J=1,sNy
       DO I=1,sNx
        HEFFprev=SItrHEFF(i,j,bi,bj,1)
#ifdef ALLOW_SITRACER_DEBUG_DIAG
        DIAGarray(I,J,5+(iTr-1)*5) =
     &    HEFFprev*SItracer(i,j,bi,bj,iTr) + SItrBucket(i,j,bi,bj,iTr)
#endif
c apply the sequence of thermodynamics increments to actual traceur
c (see seaice_growth.F)
c (jTh=1 tendency due to ice-ocean interaction)
c (jTh=2 tendency due to the atmosphere, over ice covered part)
c (jTh=3 tendency due to the atmosphere, over open water part)
c (jTh=4 tendency due to flooding)
        DO jTh=1,3
         HEFFprev=SItrHEFF(i,j,bi,bj,jTh)
         HEFFpost=SItrHEFF(i,j,bi,bj,jTh+1)
c compute ratio in [0. 1.] range for either growth or melt
         growFact=1. _d 0
         meltPart=0. _d 0
         if (HEFFpost.GT.HEFFprev) growFact=HEFFprev/HEFFpost
         if (HEFFpost.LT.HEFFprev) meltPart=HEFFprev-HEFFpost
c update SItr accordingly
         SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*growFact
     &                      +SItrFromOcean(i,j)*(1. _d 0 - growFact)
         SItrBucket(i,j,bi,bj,iTr)=SItrBucket(i,j,bi,bj,iTr)
     &             -HEFFpost*SItrFromOcean(i,j)*(1. _d 0 - growFact)
         SItrBucket(i,j,bi,bj,iTr)=SItrBucket(i,j,bi,bj,iTr)
     &                            +meltPart*SItracer(i,j,bi,bj,iTr)
        ENDDO
c apply flooding term
        growFact=1. _d 0
        HEFFprev=SItrHEFF(i,j,bi,bj,4)
        HEFFpost=SItrHEFF(i,j,bi,bj,5)
        if (HEFFpost.GT.HEFFprev) growFact=HEFFprev/HEFFpost
        SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*growFact
     &                     +SItrFromFlood(i,j) *(1. _d 0 - growFact)
c rk: flooding can only imply an ocean-ice tracer exchange, as long
c as we dont have snow tracers, so it goes through SItrBucket.
          SItrBucket(i,j,bi,bj,iTr)=SItrBucket(i,j,bi,bj,iTr)
     &             -HEFFpost*SItrFromFlood(i,j)*(1. _d 0 - growFact)
#ifdef ALLOW_SITRACER_DEBUG_DIAG
        DIAGarray(I,J,5+(iTr-1)*5) = HEFFpost*SItracer(i,j,bi,bj,iTr)
     &  +SItrBucket(i,j,bi,bj,iTr)-DIAGarray(I,J,5+(iTr-1)*5)
#endif
       ENDDO
      ENDDO
c TAF?      if (SItrMate(iTr).EQ.'AREA') then
      else
c 1) or seaice cover expansion
c ============================
c this is much simpler than for ice volume/mass tracers, because
c properties of the ice surface are not be conserved across the
c ocean-ice system, the contraction/expansion terms are all
c simultaneous (which is sane), and the only generic effect
c is due to expansion (new cover).
      DO J=1,sNy
       DO I=1,sNx
c apply expansion
        AREAprev=SItrAREA(i,j,bi,bj,2)
        AREApost=SItrAREA(i,j,bi,bj,3)
c compute ratio in [0. 1.] range for expansion/contraction
        expandFact=1. _d 0
        if (AREApost.GT.AREAprev) expandFact=AREAprev/AREApost
c update SItr accordingly
         SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*expandFact
     &                      +SItrExpand(i,j)*(1. _d 0 - expandFact)
       ENDDO
      ENDDO
      endif
c 2) very ice tracer processes
c ============================
      if (SItrName(iTr).EQ.'age') then
c age tracer: grow old as time passes by
       DO J=1,sNy
        DO I=1,sNx
          if (( (SItrHEFF(i,j,bi,bj,5).GT.0. _d 0).AND.(SItrMate(iTr)
     &     .EQ.'HEFF') ).OR.( (SItrAREA(i,j,bi,bj,3).GT.0. _d 0).AND.
     &     (SItrMate(iTr).EQ.'AREA') )) then
            SItracer(i,j,bi,bj,iTr)=
     &      SItracer(i,j,bi,bj,iTr)+SEAICE_deltaTtherm
          else
            SItracer(i,j,bi,bj,iTr)=0. _d 0
          endif
        ENDDO
       ENDDO
      elseif (SItrName(iTr).EQ.'salinity') then
c salinity tracer: no specific process
      elseif (SItrName(iTr).EQ.'one') then
c "ice concentration" tracer: no specific process
      elseif (SItrName(iTr).EQ.'ridge') then
c simple, made up, ice surface roughness index prototype
       DO J=1,sNy
        DO I=1,sNx
c ridging increases roughness
          SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)+
     &    MAX(0. _d 0, SItrAREA(i,j,bi,bj,1)-SItrAREA(i,j,bi,bj,2))
c ice melt reduces ridges/roughness
          HEFFprev=SItrHEFF(i,j,bi,bj,1)
          HEFFpost=SItrHEFF(i,j,bi,bj,4)
          tmpscal1=1. _d 0
          if (HEFFprev.GT.HEFFpost) tmpscal1=HEFFpost/HEFFprev
          SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*tmpscal1
        ENDDO
       ENDDO
      endif
c 3) ice-ocean tracer exchange/mapping to external variables
c ==========================================================
#ifdef ALLOW_DIAGNOSTICS
      IF ( useDiagnostics .AND. SItrMate(iTr).EQ.'HEFF') THEN
        WRITE(diagName,'(A4,I2.2,A2)') 'SItr',iTr,'Fx'
        tmpscal1=-ONE/SEAICE_deltaTtherm*SEAICE_rhoIce
        CALL DIAGNOSTICS_SCALE_FILL(SItrBucket(1-OLx,1-OLy,bi,bj,iTr),
     &   tmpscal1, 1, diagName,0,1,2,bi,bj,myThid)
      ENDIF
#endif

      if ( (SItrName(iTr).EQ.'salinity').AND.
     &     (SEAICE_salinityTracer) ) then
c salinity tracer: salt flux
        DO J=1,sNy
         DO I=1,sNx
          saltFlux(I,J,bi,bj) = - SItrBucket(i,j,bi,bj,iTr)
     &      *HEFFM(I,J,bi,bj)/SEAICE_deltaTtherm*SEAICE_rhoIce
c note: at this point of the time step, that is the correct sign
#ifdef ALLOW_SALT_PLUME
c should work for both constant and variable ice salinity -- to be tested
          saltPlumeFlux(I,J,bi,bj) = MAX(ZERO,saltFlux(I,J,bi,bj))
     &      *SPsalFRAC*(salt(I,j,ks,bi,bj)-SItrFromOcean(i,j))
#endif
         ENDDO
        ENDDO
      endif

      DO J=1,sNy
       DO I=1,sNx
#ifdef ALLOW_SITRACER_DEBUG_DIAG
        DIAGarray(I,J,4+(iTr-1)*5) = - SItrBucket(i,j,bi,bj,iTr)
     &  *HEFFM(I,J,bi,bj)/SEAICE_deltaTtherm*SEAICE_rhoIce
#endif
c empty bucket
        SItrBucket(i,j,bi,bj,iTr)=0. _d 0
       ENDDO
      ENDDO

c TAF? elseif (SItrMate(iTr).EQ.'AREA') then

c 4) diagnostics
c ==============
#ifdef ALLOW_SITRACER_DEBUG_DIAG
      if (SItrMate(iTr).EQ.'HEFF') then
      DO J=1,sNy
       DO I=1,sNx
        HEFFpost=SItrHEFF(i,j,bi,bj,5)
        DIAGarray(I,J,1+(iTr-1)*5) = SItracer(i,j,bi,bj,iTr)
        DIAGarray(I,J,2+(iTr-1)*5) = SItracer(i,j,bi,bj,iTr)*HEFFpost
c DIAGarray(:,:,3) is the term of comparison for DIAGarray(:,:,2)
        if (SItrName(iTr).EQ.'salinity') then
          DIAGarray(I,J,3+(iTr-1)*5) = HSALT(i,j,bi,bj)/SEAICE_rhoIce
        elseif (SItrName(iTr).EQ.'one') then
          DIAGarray(I,J,3+(iTr-1)*5) = HEFFpost
        endif
c DIAGarray(:,:,4) allows check of conservation : del(SItrBucket)+del(SItr*HEFF)=0. over do_phys
c DIAGarray(:,:,5) is the tracer flux from the ocean (<0 incr. ocean tracer)
       ENDDO
      ENDDO
      else
      DO J=1,sNy
       DO I=1,sNx
        AREApost=SItrAREA(i,j,bi,bj,3)
        DIAGarray(I,J,1+(iTr-1)*5) = SItracer(i,j,bi,bj,iTr)
        DIAGarray(I,J,2+(iTr-1)*5) = SItracer(i,j,bi,bj,iTr)*AREApost
       ENDDO
      ENDDO
      endif
#endif
      ENDDO
#ifdef ALLOW_SITRACER_DEBUG_DIAG
c     CALL DIAGNOSTICS_FILL(DIAGarray,'UDIAG1  ',0,Nr,3,bi,bj,myThid)
#endif
      ENDDO
      ENDDO

#endif /* ALLOW_SITRACER */

      RETURN
      END
1	jmc	1.10	C $Header: /u/gcmpack/MITgcm/pkg/seaice/seaice_tracer_phys.F,v 1.9 2012/12/27 23:05:47 gforget Exp $
2	gforget	1.1	C $Name: $
3
4			#include "SEAICE_OPTIONS.h"
5
6			CStartOfInterface
7			SUBROUTINE SEAICE_TRACER_PHYS( myTime, myIter, myThid )
8	jmc	1.7	C =======================================================
9			C \| SUBROUTINE seaice_tracer_phys
10			C \| o Time step SItr/SItrEFF as a result of
11			C \| seaice thermodynamics and specific tracer physics
12			C =======================================================
13	gforget	1.1	IMPLICIT NONE
14
15			C === Global variables ===
16			#include "SIZE.h"
17			#include "EEPARAMS.h"
18	jmc	1.10	#include "PARAMS.h"
19	gforget	1.1	#include "FFIELDS.h"
20			#include "DYNVARS.h"
21			#include "SEAICE_SIZE.h"
22			#include "SEAICE.h"
23			#include "SEAICE_PARAMS.h"
24			#include "SEAICE_TRACER.h"
25	gforget	1.6	#ifdef ALLOW_SALT_PLUME
26			# include "SALT_PLUME.h"
27			#endif
28	gforget	1.1
29			C === Routine arguments ===
30			C INPUT:
31			C myTime :: Simulation time
32			C myIter :: Simulation timestep number
33			C myThid :: Thread no. that called this routine.
34			C OUTPUT:
35			_RL myTime
36			INTEGER myIter, myThid
37			CEndOfInterface
38
39			C === Local variables ===
40			#ifdef ALLOW_SITRACER
41
42			INTEGER iTr, jTh, I, J, bi, bj, ks
43			_RL SItrFromOcean (1:sNx,1:sNy)
44	gforget	1.2	_RL SItrFromFlood (1:sNx,1:sNy)
45	gforget	1.1	_RL HEFFprev, HEFFpost, growFact, meltPart, tmpscal1
46	gforget	1.2	_RL SItrExpand (1:sNx,1:sNy)
47			_RL AREAprev, AREApost, expandFact
48	gforget	1.3	CHARACTER*8 diagName
49	gforget	1.1
50	gforget	1.3	#ifdef ALLOW_SITRACER_DEBUG_DIAG
51	gforget	1.1	_RL DIAGarray (1:sNx,1:sNy,Nr)
52			#endif
53
54			cgf for now I do not fully account for ocean-ice fluxes of tracer
55			cgf -> I just prescribe it consistent with age tracer
56			cgf eventually I will need to handle them as function params
57
58			ks=1
59
60			DO bj=myByLo(myThid),myByHi(myThid)
61			DO bi=myBxLo(myThid),myBxHi(myThid)
62	gforget	1.6	DO iTr=1,SItrNumInUse
63	gforget	1.1
64	jmc	1.4	c 0) set ice-ocean and ice-snow exchange values
65	gforget	1.1	c =============================================
66			DO J=1,sNy
67			DO I=1,sNx
68	gforget	1.6	SItrFromOcean(i,j)=SItrFromOcean0(iTr)
69			SItrFromFlood(i,j)=SItrFromFlood0(iTr)
70			SItrExpand(i,j)=SItrExpand0(iTr)
71	gforget	1.1	ENDDO
72			ENDDO
73	jmc	1.4	c salinity tracer:
74	jmc	1.7	if ( (SItrName(iTr).EQ.'salinity').AND.
75	gforget	1.6	& (SItrFromOceanFrac(iTr).GT.ZERO) ) then
76	gforget	1.1	DO J=1,sNy
77			DO I=1,sNx
78	gforget	1.6	SItrFromOcean(i,j)=SItrFromOceanFrac(iTr)*salt(I,j,ks,bi,bj)
79			SItrFromFlood(i,j)=SItrFromFloodFrac(iTr)*salt(I,j,ks,bi,bj)
80	gforget	1.1	ENDDO
81			ENDDO
82			endif
83			c 1) seaice thermodynamics processes
84			c ==================================
85	gforget	1.2	if (SItrMate(iTr).EQ.'HEFF') then
86	gforget	1.1	DO J=1,sNy
87			DO I=1,sNx
88			HEFFprev=SItrHEFF(i,j,bi,bj,1)
89	gforget	1.3	#ifdef ALLOW_SITRACER_DEBUG_DIAG
90	jmc	1.4	DIAGarray(I,J,5+(iTr-1)*5) =
91	gforget	1.1	& HEFFprev*SItracer(i,j,bi,bj,iTr) + SItrBucket(i,j,bi,bj,iTr)
92			#endif
93			c apply the sequence of thermodynamics increments to actual traceur
94			c (see seaice_growth.F)
95			c (jTh=1 tendency due to ice-ocean interaction)
96			c (jTh=2 tendency due to the atmosphere, over ice covered part)
97			c (jTh=3 tendency due to the atmosphere, over open water part)
98			c (jTh=4 tendency due to flooding)
99			DO jTh=1,3
100			HEFFprev=SItrHEFF(i,j,bi,bj,jTh)
101			HEFFpost=SItrHEFF(i,j,bi,bj,jTh+1)
102			c compute ratio in [0. 1.] range for either growth or melt
103			growFact=1. _d 0
104			meltPart=0. _d 0
105			if (HEFFpost.GT.HEFFprev) growFact=HEFFprev/HEFFpost
106			if (HEFFpost.LT.HEFFprev) meltPart=HEFFprev-HEFFpost
107			c update SItr accordingly
108			SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*growFact
109			& +SItrFromOcean(i,j)*(1. _d 0 - growFact)
110			SItrBucket(i,j,bi,bj,iTr)=SItrBucket(i,j,bi,bj,iTr)
111			& -HEFFpostSItrFromOcean(i,j)(1. _d 0 - growFact)
112			SItrBucket(i,j,bi,bj,iTr)=SItrBucket(i,j,bi,bj,iTr)
113			& +meltPart*SItracer(i,j,bi,bj,iTr)
114			ENDDO
115			c apply flooding term
116			growFact=1. _d 0
117			HEFFprev=SItrHEFF(i,j,bi,bj,4)
118			HEFFpost=SItrHEFF(i,j,bi,bj,5)
119			if (HEFFpost.GT.HEFFprev) growFact=HEFFprev/HEFFpost
120			SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*growFact
121	gforget	1.2	& +SItrFromFlood(i,j) *(1. _d 0 - growFact)
122			c rk: flooding can only imply an ocean-ice tracer exchange, as long
123			c as we dont have snow tracers, so it goes through SItrBucket.
124	gforget	1.1	SItrBucket(i,j,bi,bj,iTr)=SItrBucket(i,j,bi,bj,iTr)
125	gforget	1.2	& -HEFFpostSItrFromFlood(i,j)(1. _d 0 - growFact)
126	gforget	1.3	#ifdef ALLOW_SITRACER_DEBUG_DIAG
127	jmc	1.4	DIAGarray(I,J,5+(iTr-1)5) = HEFFpostSItracer(i,j,bi,bj,iTr)
128	gforget	1.3	& +SItrBucket(i,j,bi,bj,iTr)-DIAGarray(I,J,5+(iTr-1)*5)
129	gforget	1.1	#endif
130			ENDDO
131			ENDDO
132	gforget	1.2	c TAF? if (SItrMate(iTr).EQ.'AREA') then
133			else
134			c 1) or seaice cover expansion
135			c ============================
136	jmc	1.4	c this is much simpler than for ice volume/mass tracers, because
137			c properties of the ice surface are not be conserved across the
138	gforget	1.2	c ocean-ice system, the contraction/expansion terms are all
139	jmc	1.4	c simultaneous (which is sane), and the only generic effect
140	gforget	1.2	c is due to expansion (new cover).
141			DO J=1,sNy
142			DO I=1,sNx
143			c apply expansion
144			AREAprev=SItrAREA(i,j,bi,bj,2)
145			AREApost=SItrAREA(i,j,bi,bj,3)
146			c compute ratio in [0. 1.] range for expansion/contraction
147			expandFact=1. _d 0
148			if (AREApost.GT.AREAprev) expandFact=AREAprev/AREApost
149			c update SItr accordingly
150			SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*expandFact
151			& +SItrExpand(i,j)*(1. _d 0 - expandFact)
152			ENDDO
153			ENDDO
154			endif
155	gforget	1.1	c 2) very ice tracer processes
156			c ============================
157			if (SItrName(iTr).EQ.'age') then
158			c age tracer: grow old as time passes by
159			DO J=1,sNy
160			DO I=1,sNx
161	gforget	1.2	if (( (SItrHEFF(i,j,bi,bj,5).GT.0. _d 0).AND.(SItrMate(iTr)
162			& .EQ.'HEFF') ).OR.( (SItrAREA(i,j,bi,bj,3).GT.0. _d 0).AND.
163			& (SItrMate(iTr).EQ.'AREA') )) then
164	gforget	1.1	SItracer(i,j,bi,bj,iTr)=
165			& SItracer(i,j,bi,bj,iTr)+SEAICE_deltaTtherm
166			else
167			SItracer(i,j,bi,bj,iTr)=0. _d 0
168			endif
169			ENDDO
170			ENDDO
171			elseif (SItrName(iTr).EQ.'salinity') then
172			c salinity tracer: no specific process
173			elseif (SItrName(iTr).EQ.'one') then
174			c "ice concentration" tracer: no specific process
175	gforget	1.2	elseif (SItrName(iTr).EQ.'ridge') then
176			c simple, made up, ice surface roughness index prototype
177			DO J=1,sNy
178			DO I=1,sNx
179			c ridging increases roughness
180			SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)+
181			& MAX(0. _d 0, SItrAREA(i,j,bi,bj,1)-SItrAREA(i,j,bi,bj,2))
182			c ice melt reduces ridges/roughness
183			HEFFprev=SItrHEFF(i,j,bi,bj,1)
184			HEFFpost=SItrHEFF(i,j,bi,bj,4)
185			tmpscal1=1. _d 0
186			if (HEFFprev.GT.HEFFpost) tmpscal1=HEFFpost/HEFFprev
187			SItracer(i,j,bi,bj,iTr)=SItracer(i,j,bi,bj,iTr)*tmpscal1
188			ENDDO
189			ENDDO
190	gforget	1.1	endif
191	gforget	1.2	c 3) ice-ocean tracer exchange/mapping to external variables
192			c ==========================================================
193	gforget	1.3	#ifdef ALLOW_DIAGNOSTICS
194	jmc	1.10	IF ( useDiagnostics .AND. SItrMate(iTr).EQ.'HEFF') THEN
195	gforget	1.8	WRITE(diagName,'(A4,I2.2,A2)') 'SItr',iTr,'Fx'
196	gforget	1.3	tmpscal1=-ONE/SEAICE_deltaTtherm*SEAICE_rhoIce
197	jmc	1.7	CALL DIAGNOSTICS_SCALE_FILL(SItrBucket(1-OLx,1-OLy,bi,bj,iTr),
198	gforget	1.3	& tmpscal1, 1, diagName,0,1,2,bi,bj,myThid)
199	jmc	1.10	ENDIF
200	gforget	1.3	#endif
201	gforget	1.6
202			if ( (SItrName(iTr).EQ.'salinity').AND.
203			& (SEAICE_salinityTracer) ) then
204	gforget	1.1	c salinity tracer: salt flux
205	gforget	1.6	DO J=1,sNy
206			DO I=1,sNx
207			saltFlux(I,J,bi,bj) = - SItrBucket(i,j,bi,bj,iTr)
208			& HEFFM(I,J,bi,bj)/SEAICE_deltaTthermSEAICE_rhoIce
209	gforget	1.1	c note: at this point of the time step, that is the correct sign
210	gforget	1.6	#ifdef ALLOW_SALT_PLUME
211			c should work for both constant and variable ice salinity -- to be tested
212	jmc	1.7	saltPlumeFlux(I,J,bi,bj) = MAX(ZERO,saltFlux(I,J,bi,bj))
213	gforget	1.6	& SPsalFRAC(salt(I,j,ks,bi,bj)-SItrFromOcean(i,j))
214			#endif
215			ENDDO
216			ENDDO
217	gforget	1.1	endif
218	jmc	1.7
219	gforget	1.1	DO J=1,sNy
220			DO I=1,sNx
221	gforget	1.3	#ifdef ALLOW_SITRACER_DEBUG_DIAG
222			DIAGarray(I,J,4+(iTr-1)*5) = - SItrBucket(i,j,bi,bj,iTr)
223	gforget	1.1	& HEFFM(I,J,bi,bj)/SEAICE_deltaTthermSEAICE_rhoIce
224			#endif
225			c empty bucket
226			SItrBucket(i,j,bi,bj,iTr)=0. _d 0
227			ENDDO
228			ENDDO
229	jmc	1.7
230	gforget	1.2	c TAF? elseif (SItrMate(iTr).EQ.'AREA') then
231	gforget	1.6
232	gforget	1.1	c 4) diagnostics
233			c ==============
234	gforget	1.3	#ifdef ALLOW_SITRACER_DEBUG_DIAG
235	gforget	1.2	if (SItrMate(iTr).EQ.'HEFF') then
236	gforget	1.1	DO J=1,sNy
237			DO I=1,sNx
238			HEFFpost=SItrHEFF(i,j,bi,bj,5)
239			DIAGarray(I,J,1+(iTr-1)*5) = SItracer(i,j,bi,bj,iTr)
240			DIAGarray(I,J,2+(iTr-1)5) = SItracer(i,j,bi,bj,iTr)HEFFpost
241	gforget	1.3	c DIAGarray(:,:,3) is the term of comparison for DIAGarray(:,:,2)
242	gforget	1.5	if (SItrName(iTr).EQ.'salinity') then
243	gforget	1.1	DIAGarray(I,J,3+(iTr-1)*5) = HSALT(i,j,bi,bj)/SEAICE_rhoIce
244			elseif (SItrName(iTr).EQ.'one') then
245			DIAGarray(I,J,3+(iTr-1)*5) = HEFFpost
246			endif
247	gforget	1.3	c DIAGarray(:,:,4) allows check of conservation : del(SItrBucket)+del(SItr*HEFF)=0. over do_phys
248			c DIAGarray(:,:,5) is the tracer flux from the ocean (<0 incr. ocean tracer)
249	gforget	1.1	ENDDO
250			ENDDO
251	gforget	1.2	else
252			DO J=1,sNy
253			DO I=1,sNx
254			AREApost=SItrAREA(i,j,bi,bj,3)
255			DIAGarray(I,J,1+(iTr-1)*5) = SItracer(i,j,bi,bj,iTr)
256			DIAGarray(I,J,2+(iTr-1)5) = SItracer(i,j,bi,bj,iTr)AREApost
257			ENDDO
258			ENDDO
259			endif
260	gforget	1.1	#endif
261			ENDDO
262	gforget	1.3	#ifdef ALLOW_SITRACER_DEBUG_DIAG
263	jmc	1.4	c CALL DIAGNOSTICS_FILL(DIAGarray,'UDIAG1 ',0,Nr,3,bi,bj,myThid)
264	gforget	1.1	#endif
265			ENDDO
266			ENDDO
267
268			#endif /* ALLOW_SITRACER */
269
270			RETURN
271			END