source: LMDZ6/branches/Amaury_dev/libf/dyn3d_common/advxp.f90 @ 5209

! $Header$

 SUBROUTINE ADVXP(LIMIT,DTX,PBARU,SM,S0,SSX,SY,SZ &
         ,SSXX,SSXY,SSXZ,SYY,SYZ,SZZ,ntra)
  USE lmdz_dimensions, ONLY: iim, jjm, llm, ndm
  USE lmdz_paramet
   IMPLICIT NONE
  !CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
  !                                                                 C
  !  second-order moments (SOM) advection of tracer in X direction  C
  !                                                                 C
  !CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC

  !  parametres principaux du modele
  !



   INTEGER :: ntra
   ! PARAMETER (ntra = 1)

  !  definition de la grille du modele

  REAL :: dtx
  REAL :: pbaru ( iip1,jjp1,llm )

  !  moments: SM  total mass in each grid box
  !       S0  mass of tracer in each grid box
  !       Si  1rst order moment in i direction
  !       Sij 2nd  order moment in i and j directions

  REAL :: SM(iip1,jjp1,llm) &
        ,S0(iip1,jjp1,llm,ntra)
  REAL :: SSX(iip1,jjp1,llm,ntra) &
        ,SY(iip1,jjp1,llm,ntra) &
        ,SZ(iip1,jjp1,llm,ntra)
  REAL :: SSXX(iip1,jjp1,llm,ntra) &
        ,SSXY(iip1,jjp1,llm,ntra) &
        ,SSXZ(iip1,jjp1,llm,ntra) &
        ,SYY(iip1,jjp1,llm,ntra) &
        ,SYZ(iip1,jjp1,llm,ntra) &
        ,SZZ(iip1,jjp1,llm,ntra)

  !  Local :
  !  -------

  !  mass fluxes across the boundaries (UGRI,VGRI,WGRI)
  !  mass fluxes in kg
  !  declaration :

   REAL :: UGRI(iip1,jjp1,llm)

  !  Rem : VGRI et WGRI ne sont pas utilises dans
  !  cette SUBROUTINE ( advection en x uniquement )


  !  Tij are the moments for the current latitude and level

  REAL :: TM (iim)
  REAL :: T0 (iim,NTRA),TX (iim,NTRA)
  REAL :: TY (iim,NTRA),TZ (iim,NTRA)
  REAL :: TXX(iim,NTRA),TXY(iim,NTRA)
  REAL :: TXZ(iim,NTRA),TYY(iim,NTRA)
  REAL :: TYZ(iim,NTRA),TZZ(iim,NTRA)

  !  the moments F are similarly defined and used as temporary
  !  storage for portions of the grid boxes in transit

  REAL :: FM (iim)
  REAL :: F0 (iim,NTRA),FX (iim,NTRA)
  REAL :: FY (iim,NTRA),FZ (iim,NTRA)
  REAL :: FXX(iim,NTRA),FXY(iim,NTRA)
  REAL :: FXZ(iim,NTRA),FYY(iim,NTRA)
  REAL :: FYZ(iim,NTRA),FZZ(iim,NTRA)

  !  work arrays

  REAL :: ALF (iim),ALF1(iim),ALFQ(iim),ALF1Q(iim)
  REAL :: ALF2(iim),ALF3(iim),ALF4(iim)

  REAL :: SMNEW(iim),UEXT(iim)
  REAL :: sqi,sqf
  REAL :: TEMPTM
  REAL :: SLPMAX
  REAL :: S1MAX,S1NEW,S2NEW

  LOGICAL :: LIMIT
  INTEGER :: NUM(jjp1),LONK,NUMK
  INTEGER :: lon,lati,latf,niv
  INTEGER :: i,i2,i3,j,jv,l,k,iter

  lon = iim
  lati=2
  latf = jjm
  niv = llm

  ! *** Test de passage d'arguments ******

   ! DO 399 l = 1, llm
   !  DO 399 j = 1, jjp1
   !   DO 399 i = 1, iip1
   !    IF (S0(i,j,l,ntra) .lt. 0. ) THEN
   !    PRINT*,'S0(',i,j,l,')=',S0(i,j,l,ntra)
   !        PRINT*, 'SSX(',i,j,l,')=',SSX(i,j,l,ntra)
   !    PRINT*, 'SY(',i,j,l,')=',SY(i,j,l,ntra)
   !    PRINT*, 'SZ(',i,j,l,')=',SZ(i,j,l,ntra)
   !    PRINT*, 'AIE !! debut ADVXP - pbl arg. passage dans ADVXP'
  !c            STOP
   !    ENDIF
  !  399 CONTINUE

  ! *** Test : diagnostique de la qtite totale de traceur
   !       dans l'atmosphere avant l'advection

  sqi =0.
  sqf =0.

  DO l = 1, llm
  DO j = 1, jjp1
  DO i = 1, iim
     sqi = sqi + S0(i,j,l,ntra)
  END DO
  END DO
  END DO
  PRINT*,'------ DIAG DANS ADVX2 - ENTREE -----'
  PRINT*,'sqi=',sqi
  ! test
  !  -------------------------------------
    DO j =1,jjp1
     NUM(j) =1
  END DO
    ! DO l=1,llm
   ! NUM(2,l)=6
   ! NUM(3,l)=6
   ! NUM(jjm-1,l)=6
   ! NUM(jjm,l)=6
   ! ENDDO
   !   DO j=2,6
   !  NUM(j)=12
   !  ENDDO
   !  DO j=jjm-5,jjm-1
   !  NUM(j)=12
   !  ENDDO

  !  Interface : adaptation nouveau modele
  !  -------------------------------------

  !  ---------------------------------------------------------
  !  Conversion des flux de masses en kg/s
  !  pbaru est en N/s d'ou :
  !  ugri est en kg/s

   DO l = 1,llm
   DO j = 1,jjp1
   DO i = 1,iip1
   ugri (i,j,llm+1-l) =pbaru (i,j,l)
  END DO
  END DO
  END DO

  !  ---------------------------------------------------------
  !  start here

  !  boucle principale sur les niveaux et les latitudes

  DO L=1,NIV
  DO K=lati,latf


  !  initialisation

  !  program assumes periodic boundaries in X

  DO I=2,LON
     SMNEW(I)=SM(I,K,L)+(UGRI(I-1,K,L)-UGRI(I,K,L))*DTX
  END DO
  SMNEW(1)=SM(1,K,L)+(UGRI(LON,K,L)-UGRI(1,K,L))*DTX

  !  modifications for extended polar zones

  NUMK=NUM(K)
  LONK=LON/NUMK

  IF(NUMK>1) THEN

  DO I=1,LON
     TM(I)=0.
  END DO
  DO JV=1,NTRA
  DO I=1,LON
     T0 (I,JV)=0.
     TX (I,JV)=0.
     TY (I,JV)=0.
     TZ (I,JV)=0.
     TXX(I,JV)=0.
     TXY(I,JV)=0.
     TXZ(I,JV)=0.
     TYY(I,JV)=0.
     TYZ(I,JV)=0.
     TZZ(I,JV)=0.
  END DO
  END DO

  DO I2=1,NUMK

     DO I=1,LONK
        I3=(I-1)*NUMK+I2
        TM(I)=TM(I)+SM(I3,K,L)
        ALF(I)=SM(I3,K,L)/TM(I)
        ALF1(I)=1.-ALF(I)
        ALFQ(I)=ALF(I)*ALF(I)
        ALF1Q(I)=ALF1(I)*ALF1(I)
        ALF2(I)=ALF1(I)-ALF(I)
        ALF3(I)=ALF(I)*ALF1(I)
  END DO

     DO JV=1,NTRA
     DO I=1,LONK
        I3=(I-1)*NUMK+I2
        TEMPTM=-ALF(I)*T0(I,JV)+ALF1(I)*S0(I3,K,L,JV)
        T0 (I,JV)=T0(I,JV)+S0(I3,K,L,JV)
        TXX(I,JV)=ALFQ(I)*SSXX(I3,K,L,JV)+ALF1Q(I)*TXX(I,JV) &
              +5.*( ALF3(I)*(SSX(I3,K,L,JV)-TX(I,JV))+ALF2(I)*TEMPTM )
        TX (I,JV)=ALF(I)*SSX(I3,K,L,JV)+ALF1(I)*TX(I,JV)+3.*TEMPTM
        TXY(I,JV)=ALF (I)*SSXY(I3,K,L,JV)+ALF1(I)*TXY(I,JV) &
              +3.*(ALF1(I)*SY (I3,K,L,JV)-ALF (I)*TY (I,JV))
        TXZ(I,JV)=ALF (I)*SSXZ(I3,K,L,JV)+ALF1(I)*TXZ(I,JV) &
              +3.*(ALF1(I)*SZ (I3,K,L,JV)-ALF (I)*TZ (I,JV))
        TY (I,JV)=TY (I,JV)+SY (I3,K,L,JV)
        TZ (I,JV)=TZ (I,JV)+SZ (I3,K,L,JV)
        TYY(I,JV)=TYY(I,JV)+SYY(I3,K,L,JV)
        TYZ(I,JV)=TYZ(I,JV)+SYZ(I3,K,L,JV)
        TZZ(I,JV)=TZZ(I,JV)+SZZ(I3,K,L,JV)
  END DO
  END DO

  END DO

  ELSE

  DO I=1,LON
     TM(I)=SM(I,K,L)
  END DO
  DO JV=1,NTRA
  DO I=1,LON
     T0 (I,JV)=S0 (I,K,L,JV)
     TX (I,JV)=SSX (I,K,L,JV)
     TY (I,JV)=SY (I,K,L,JV)
     TZ (I,JV)=SZ (I,K,L,JV)
     TXX(I,JV)=SSXX(I,K,L,JV)
     TXY(I,JV)=SSXY(I,K,L,JV)
     TXZ(I,JV)=SSXZ(I,K,L,JV)
     TYY(I,JV)=SYY(I,K,L,JV)
     TYZ(I,JV)=SYZ(I,K,L,JV)
     TZZ(I,JV)=SZZ(I,K,L,JV)
  END DO
  END DO

  ENDIF

  DO I=1,LONK
     UEXT(I)=UGRI(I*NUMK,K,L)
  END DO

  !  place limits on appropriate moments before transport
  !  (if flux-limiting is to be applied)

  IF(.NOT.LIMIT) GO TO 13

  DO JV=1,NTRA
  DO I=1,LONK
    IF(T0(I,JV)>0.) THEN
      SLPMAX=T0(I,JV)
      S1MAX=1.5*SLPMAX
      S1NEW=AMIN1(S1MAX,AMAX1(-S1MAX,TX(I,JV)))
      S2NEW=AMIN1( 2.*SLPMAX-ABS(S1NEW)/3. , &
            AMAX1(ABS(S1NEW)-SLPMAX,TXX(I,JV)) )
      TX (I,JV)=S1NEW
      TXX(I,JV)=S2NEW
      TXY(I,JV)=AMIN1(SLPMAX,AMAX1(-SLPMAX,TXY(I,JV)))
      TXZ(I,JV)=AMIN1(SLPMAX,AMAX1(-SLPMAX,TXZ(I,JV)))
    ELSE
      TX (I,JV)=0.
      TXX(I,JV)=0.
      TXY(I,JV)=0.
      TXZ(I,JV)=0.
    ENDIF
  END DO
  END DO

 13   CONTINUE

  !  calculate flux and moments between adjacent boxes
  !  1- create temporary moments/masses for partial boxes in transit
  !  2- reajusts moments remaining in the box

  !  flux from IP to I if U(I).lt.0

  DO I=1,LONK-1
     IF(UEXT(I)<0.) THEN
       FM(I)=-UEXT(I)*DTX
       ALF(I)=FM(I)/TM(I+1)
       TM(I+1)=TM(I+1)-FM(I)
     ENDIF
  END DO

  I=LONK
  IF(UEXT(I)<0.) THEN
    FM(I)=-UEXT(I)*DTX
    ALF(I)=FM(I)/TM(1)
    TM(1)=TM(1)-FM(I)
  ENDIF

  !  flux from I to IP if U(I).gt.0

  DO I=1,LONK
     IF(UEXT(I)>=0.) THEN
       FM(I)=UEXT(I)*DTX
       ALF(I)=FM(I)/TM(I)
       TM(I)=TM(I)-FM(I)
     ENDIF
  END DO

  DO I=1,LONK
     ALFQ(I)=ALF(I)*ALF(I)
     ALF1(I)=1.-ALF(I)
     ALF1Q(I)=ALF1(I)*ALF1(I)
     ALF2(I)=ALF1(I)-ALF(I)
     ALF3(I)=ALF(I)*ALFQ(I)
     ALF4(I)=ALF1(I)*ALF1Q(I)
  END DO

  DO JV=1,NTRA
  DO I=1,LONK-1

     IF(UEXT(I)<0.) THEN

       F0 (I,JV)=ALF (I)* ( T0(I+1,JV)-ALF1(I)* &
             ( TX(I+1,JV)-ALF2(I)*TXX(I+1,JV) ) )
       FX (I,JV)=ALFQ(I)*(TX(I+1,JV)-3.*ALF1(I)*TXX(I+1,JV))
       FXX(I,JV)=ALF3(I)*TXX(I+1,JV)
       FY (I,JV)=ALF (I)*(TY(I+1,JV)-ALF1(I)*TXY(I+1,JV))
       FZ (I,JV)=ALF (I)*(TZ(I+1,JV)-ALF1(I)*TXZ(I+1,JV))
       FXY(I,JV)=ALFQ(I)*TXY(I+1,JV)
       FXZ(I,JV)=ALFQ(I)*TXZ(I+1,JV)
       FYY(I,JV)=ALF (I)*TYY(I+1,JV)
       FYZ(I,JV)=ALF (I)*TYZ(I+1,JV)
       FZZ(I,JV)=ALF (I)*TZZ(I+1,JV)

       T0 (I+1,JV)=T0(I+1,JV)-F0(I,JV)
       TX (I+1,JV)=ALF1Q(I)*(TX(I+1,JV)+3.*ALF(I)*TXX(I+1,JV))
       TXX(I+1,JV)=ALF4(I)*TXX(I+1,JV)
       TY (I+1,JV)=TY (I+1,JV)-FY (I,JV)
       TZ (I+1,JV)=TZ (I+1,JV)-FZ (I,JV)
       TYY(I+1,JV)=TYY(I+1,JV)-FYY(I,JV)
       TYZ(I+1,JV)=TYZ(I+1,JV)-FYZ(I,JV)
       TZZ(I+1,JV)=TZZ(I+1,JV)-FZZ(I,JV)
       TXY(I+1,JV)=ALF1Q(I)*TXY(I+1,JV)
       TXZ(I+1,JV)=ALF1Q(I)*TXZ(I+1,JV)

     ENDIF

  END DO
  END DO

  I=LONK
  IF(UEXT(I)<0.) THEN

    DO JV=1,NTRA

       F0 (I,JV)=ALF (I)* ( T0(1,JV)-ALF1(I)* &
             ( TX(1,JV)-ALF2(I)*TXX(1,JV) ) )
       FX (I,JV)=ALFQ(I)*(TX(1,JV)-3.*ALF1(I)*TXX(1,JV))
       FXX(I,JV)=ALF3(I)*TXX(1,JV)
       FY (I,JV)=ALF (I)*(TY(1,JV)-ALF1(I)*TXY(1,JV))
       FZ (I,JV)=ALF (I)*(TZ(1,JV)-ALF1(I)*TXZ(1,JV))
       FXY(I,JV)=ALFQ(I)*TXY(1,JV)
       FXZ(I,JV)=ALFQ(I)*TXZ(1,JV)
       FYY(I,JV)=ALF (I)*TYY(1,JV)
       FYZ(I,JV)=ALF (I)*TYZ(1,JV)
       FZZ(I,JV)=ALF (I)*TZZ(1,JV)

       T0 (1,JV)=T0(1,JV)-F0(I,JV)
       TX (1,JV)=ALF1Q(I)*(TX(1,JV)+3.*ALF(I)*TXX(1,JV))
       TXX(1,JV)=ALF4(I)*TXX(1,JV)
       TY (1,JV)=TY (1,JV)-FY (I,JV)
       TZ (1,JV)=TZ (1,JV)-FZ (I,JV)
       TYY(1,JV)=TYY(1,JV)-FYY(I,JV)
       TYZ(1,JV)=TYZ(1,JV)-FYZ(I,JV)
       TZZ(1,JV)=TZZ(1,JV)-FZZ(I,JV)
       TXY(1,JV)=ALF1Q(I)*TXY(1,JV)
       TXZ(1,JV)=ALF1Q(I)*TXZ(1,JV)

  END DO

  ENDIF

  DO JV=1,NTRA
  DO I=1,LONK

     IF(UEXT(I)>=0.) THEN

       F0 (I,JV)=ALF (I)* ( T0(I,JV)+ALF1(I)* &
             ( TX(I,JV)+ALF2(I)*TXX(I,JV) ) )
       FX (I,JV)=ALFQ(I)*(TX(I,JV)+3.*ALF1(I)*TXX(I,JV))
       FXX(I,JV)=ALF3(I)*TXX(I,JV)
       FY (I,JV)=ALF (I)*(TY(I,JV)+ALF1(I)*TXY(I,JV))
       FZ (I,JV)=ALF (I)*(TZ(I,JV)+ALF1(I)*TXZ(I,JV))
       FXY(I,JV)=ALFQ(I)*TXY(I,JV)
       FXZ(I,JV)=ALFQ(I)*TXZ(I,JV)
       FYY(I,JV)=ALF (I)*TYY(I,JV)
       FYZ(I,JV)=ALF (I)*TYZ(I,JV)
       FZZ(I,JV)=ALF (I)*TZZ(I,JV)

       T0 (I,JV)=T0(I,JV)-F0(I,JV)
       TX (I,JV)=ALF1Q(I)*(TX(I,JV)-3.*ALF(I)*TXX(I,JV))
       TXX(I,JV)=ALF4(I)*TXX(I,JV)
       TY (I,JV)=TY (I,JV)-FY (I,JV)
       TZ (I,JV)=TZ (I,JV)-FZ (I,JV)
       TYY(I,JV)=TYY(I,JV)-FYY(I,JV)
       TYZ(I,JV)=TYZ(I,JV)-FYZ(I,JV)
       TZZ(I,JV)=TZZ(I,JV)-FZZ(I,JV)
       TXY(I,JV)=ALF1Q(I)*TXY(I,JV)
       TXZ(I,JV)=ALF1Q(I)*TXZ(I,JV)

     ENDIF

  END DO
  END DO

  !  puts the temporary moments Fi into appropriate neighboring boxes

  DO I=1,LONK
     IF(UEXT(I)<0.) THEN
       TM(I)=TM(I)+FM(I)
       ALF(I)=FM(I)/TM(I)
     ENDIF
  END DO

  DO I=1,LONK-1
     IF(UEXT(I)>=0.) THEN
       TM(I+1)=TM(I+1)+FM(I)
       ALF(I)=FM(I)/TM(I+1)
     ENDIF
  END DO

  I=LONK
  IF(UEXT(I)>=0.) THEN
    TM(1)=TM(1)+FM(I)
    ALF(I)=FM(I)/TM(1)
  ENDIF

  DO I=1,LONK
     ALF1(I)=1.-ALF(I)
     ALFQ(I)=ALF(I)*ALF(I)
     ALF1Q(I)=ALF1(I)*ALF1(I)
     ALF2(I)=ALF1(I)-ALF(I)
     ALF3(I)=ALF(I)*ALF1(I)
  END DO

  DO JV=1,NTRA
  DO I=1,LONK

     IF(UEXT(I)<0.) THEN

       TEMPTM=-ALF(I)*T0(I,JV)+ALF1(I)*F0(I,JV)
       T0 (I,JV)=T0(I,JV)+F0(I,JV)
       TXX(I,JV)=ALFQ(I)*FXX(I,JV)+ALF1Q(I)*TXX(I,JV) &
             +5.*( ALF3(I)*(FX(I,JV)-TX(I,JV))+ALF2(I)*TEMPTM )
       TX (I,JV)=ALF (I)*FX (I,JV)+ALF1(I)*TX (I,JV)+3.*TEMPTM
       TXY(I,JV)=ALF (I)*FXY(I,JV)+ALF1(I)*TXY(I,JV) &
             +3.*(ALF1(I)*FY (I,JV)-ALF (I)*TY (I,JV))
       TXZ(I,JV)=ALF (I)*FXZ(I,JV)+ALF1(I)*TXZ(I,JV) &
             +3.*(ALF1(I)*FZ (I,JV)-ALF (I)*TZ (I,JV))
       TY (I,JV)=TY (I,JV)+FY (I,JV)
       TZ (I,JV)=TZ (I,JV)+FZ (I,JV)
       TYY(I,JV)=TYY(I,JV)+FYY(I,JV)
       TYZ(I,JV)=TYZ(I,JV)+FYZ(I,JV)
       TZZ(I,JV)=TZZ(I,JV)+FZZ(I,JV)

     ENDIF

  END DO
  END DO

  DO JV=1,NTRA
  DO I=1,LONK-1

     IF(UEXT(I)>=0.) THEN

       TEMPTM=ALF(I)*T0(I+1,JV)-ALF1(I)*F0(I,JV)
       T0 (I+1,JV)=T0(I+1,JV)+F0(I,JV)
       TXX(I+1,JV)=ALFQ(I)*FXX(I,JV)+ALF1Q(I)*TXX(I+1,JV) &
             +5.*( ALF3(I)*(TX(I+1,JV)-FX(I,JV))-ALF2(I)*TEMPTM )
       TX (I+1,JV)=ALF(I)*FX (I  ,JV)+ALF1(I)*TX (I+1,JV)+3.*TEMPTM
       TXY(I+1,JV)=ALF(I)*FXY(I  ,JV)+ALF1(I)*TXY(I+1,JV) &
             +3.*(ALF(I)*TY (I+1,JV)-ALF1(I)*FY (I  ,JV))
       TXZ(I+1,JV)=ALF(I)*FXZ(I  ,JV)+ALF1(I)*TXZ(I+1,JV) &
             +3.*(ALF(I)*TZ (I+1,JV)-ALF1(I)*FZ (I  ,JV))
       TY (I+1,JV)=TY (I+1,JV)+FY (I,JV)
       TZ (I+1,JV)=TZ (I+1,JV)+FZ (I,JV)
       TYY(I+1,JV)=TYY(I+1,JV)+FYY(I,JV)
       TYZ(I+1,JV)=TYZ(I+1,JV)+FYZ(I,JV)
       TZZ(I+1,JV)=TZZ(I+1,JV)+FZZ(I,JV)

     ENDIF

  END DO
  END DO

  I=LONK
  IF(UEXT(I)>=0.) THEN
    DO JV=1,NTRA
       TEMPTM=ALF(I)*T0(1,JV)-ALF1(I)*F0(I,JV)
       T0 (1,JV)=T0(1,JV)+F0(I,JV)
       TXX(1,JV)=ALFQ(I)*FXX(I,JV)+ALF1Q(I)*TXX(1,JV) &
             +5.*( ALF3(I)*(TX(1,JV)-FX(I,JV))-ALF2(I)*TEMPTM )
       TX (1,JV)=ALF(I)*FX(I,JV)+ALF1(I)*TX(1,JV)+3.*TEMPTM
       TXY(1,JV)=ALF(I)*FXY(I,JV)+ALF1(I)*TXY(1,JV) &
             +3.*(ALF(I)*TY (1,JV)-ALF1(I)*FY (I,JV))
       TXZ(1,JV)=ALF(I)*FXZ(I,JV)+ALF1(I)*TXZ(1,JV) &
             +3.*(ALF(I)*TZ (1,JV)-ALF1(I)*FZ (I,JV))
       TY (1,JV)=TY (1,JV)+FY (I,JV)
       TZ (1,JV)=TZ (1,JV)+FZ (I,JV)
       TYY(1,JV)=TYY(1,JV)+FYY(I,JV)
       TYZ(1,JV)=TYZ(1,JV)+FYZ(I,JV)
       TZZ(1,JV)=TZZ(1,JV)+FZZ(I,JV)
  END DO
  ENDIF

  !  retour aux mailles d'origine (passage des Tij aux Sij)

  IF(NUMK>1) THEN

  DO I2=1,NUMK

     DO I=1,LONK

        I3=I2+(I-1)*NUMK
        SM(I3,K,L)=SMNEW(I3)
        ALF(I)=SMNEW(I3)/TM(I)
        TM(I)=TM(I)-SMNEW(I3)

        ALFQ(I)=ALF(I)*ALF(I)
        ALF1(I)=1.-ALF(I)
        ALF1Q(I)=ALF1(I)*ALF1(I)
        ALF2(I)=ALF1(I)-ALF(I)
        ALF3(I)=ALF(I)*ALFQ(I)
        ALF4(I)=ALF1(I)*ALF1Q(I)

  END DO

     DO JV=1,NTRA
     DO I=1,LONK

        I3=I2+(I-1)*NUMK
        S0 (I3,K,L,JV)=ALF (I)* ( T0(I,JV)-ALF1(I)* &
              ( TX(I,JV)-ALF2(I)*TXX(I,JV) ) )
        SSX (I3,K,L,JV)=ALFQ(I)*(TX(I,JV)-3.*ALF1(I)*TXX(I,JV))
        SSXX(I3,K,L,JV)=ALF3(I)*TXX(I,JV)
        SY (I3,K,L,JV)=ALF (I)*(TY(I,JV)-ALF1(I)*TXY(I,JV))
        SZ (I3,K,L,JV)=ALF (I)*(TZ(I,JV)-ALF1(I)*TXZ(I,JV))
        SSXY(I3,K,L,JV)=ALFQ(I)*TXY(I,JV)
        SSXZ(I3,K,L,JV)=ALFQ(I)*TXZ(I,JV)
        SYY(I3,K,L,JV)=ALF (I)*TYY(I,JV)
        SYZ(I3,K,L,JV)=ALF (I)*TYZ(I,JV)
        SZZ(I3,K,L,JV)=ALF (I)*TZZ(I,JV)

  !   reajusts moments remaining in the box

        T0 (I,JV)=T0(I,JV)-S0(I3,K,L,JV)
        TX (I,JV)=ALF1Q(I)*(TX(I,JV)+3.*ALF(I)*TXX(I,JV))
        TXX(I,JV)=ALF4 (I)*TXX(I,JV)
        TY (I,JV)=TY (I,JV)-SY (I3,K,L,JV)
        TZ (I,JV)=TZ (I,JV)-SZ (I3,K,L,JV)
        TYY(I,JV)=TYY(I,JV)-SYY(I3,K,L,JV)
        TYZ(I,JV)=TYZ(I,JV)-SYZ(I3,K,L,JV)
        TZZ(I,JV)=TZZ(I,JV)-SZZ(I3,K,L,JV)
        TXY(I,JV)=ALF1Q(I)*TXY(I,JV)
        TXZ(I,JV)=ALF1Q(I)*TXZ(I,JV)

  END DO
  END DO

  END DO

  ELSE

  DO I=1,LON
     SM(I,K,L)=TM(I)
  END DO
  DO JV=1,NTRA
  DO I=1,LON
     S0 (I,K,L,JV)=T0 (I,JV)
     SSX (I,K,L,JV)=TX (I,JV)
     SY (I,K,L,JV)=TY (I,JV)
     SZ (I,K,L,JV)=TZ (I,JV)
     SSXX(I,K,L,JV)=TXX(I,JV)
     SSXY(I,K,L,JV)=TXY(I,JV)
     SSXZ(I,K,L,JV)=TXZ(I,JV)
     SYY(I,K,L,JV)=TYY(I,JV)
     SYZ(I,K,L,JV)=TYZ(I,JV)
     SZZ(I,K,L,JV)=TZZ(I,JV)
  END DO
  END DO

  ENDIF

  END DO
  END DO

  ! ----------- AA Test en fin de ADVX ------ Controle des S*

  !  DO 9999 l = 1, llm
  !  DO 9999 j = 1, jjp1
  !  DO 9999 i = 1, iip1
  !       IF (S0(i,j,l,ntra).lt.0..and.LIMIT) THEN
  !       PRINT*, '-------------------'
  !            PRINT*, 'En fin de ADVXP'
  !       PRINT*,'S0(',i,j,l,')=',S0(i,j,l,ntra)
  !            PRINT*, 'SSX(',i,j,l,')=',SSX(i,j,l,ntra)
  !       PRINT*, 'SY(',i,j,l,')=',SY(i,j,l,ntra)
  !           PRINT*, 'SZ(',i,j,l,')=',SZ(i,j,l,ntra)
  !        WRITE (*,*) 'On arrete !! - pbl en fin de ADVXP'
  !        STOP
  !       ENDIF
  ! 9999 CONTINUE
  ! ---------- bouclage cyclique

  DO l = 1,llm
  DO j = 1,jjp1
     SM(iip1,j,l) = SM(1,j,l)
     S0(iip1,j,l,ntra) = S0(1,j,l,ntra)
          SSX(iip1,j,l,ntra) = SSX(1,j,l,ntra)
         SY(iip1,j,l,ntra) = SY(1,j,l,ntra)
         SZ(iip1,j,l,ntra) = SZ(1,j,l,ntra)
  END DO
  END DO

  ! ----------- qqtite totale de traceur dans tte l'atmosphere
  DO l = 1, llm
  DO j = 1, jjp1
  DO i = 1, iim
    sqf = sqf + S0(i,j,l,ntra)
  END DO
  END DO
  END DO

  PRINT*,'------ DIAG DANS ADVX2 - SORTIE -----'
  PRINT*,'sqf=',sqf
  !-------------------------------------------------------------
  RETURN
END SUBROUTINE ADVXP