source: trunk/LMDZ.MARS/libf/phymars/calltherm_interface.F90 @ 2154

Last change on this file since 2154 was 1226, checked in by aslmd, 11 years ago

LMDZ.MARS : Replaced comcstfi and planete includes by modules.

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1!=======================================================================
2! CALLTHERM_INTERFACE
3!=======================================================================
4! Main interface to the Martian thermal plume model
5! This interface handles sub-timesteps for this model
6! A call to this interface must be inserted in the main 'physics' routine
7!   NB: for information:
8!   In the Mars LMD-GCM, the thermal plume model is called after
9!   the vertical turbulent mixing scheme (Mellor and Yamada) 
10!   and the surface layer scheme (Richardson-based surface layer + subgrid gustiness)
11!   Other routines called before the thermals model are
12!   radiative transfer and (orographic) gravity wave drag.
13! -----------------------------------------------------------------------
14! Author : A. Colaitis 2011-01-05 (with updates 2011-2013)
15!          after C. Rio and F. Hourdin
16! Institution : Laboratoire de Meteorologie Dynamique (LMD) Paris, France
17! -----------------------------------------------------------------------
18! Corresponding author : A. Spiga aymeric.spiga_AT_upmc.fr
19! -----------------------------------------------------------------------
20! ASSOCIATED FILES
21! --> thermcell_main_mars.F90
22! --> thermcell_dqup.F90
23! --> comtherm_h.F90
24! -----------------------------------------------------------------------
25! Reference paper:
26! A. Colaïtis, A. Spiga, F. Hourdin, C. Rio, F. Forget, and E. Millour.
27! A thermal plume model for the Martian convective boundary layer.
28! Journal of Geophysical Research (Planets), 118:1468-1487, July 2013.
29! http://dx.doi.org/10.1002/jgre.20104
30! http://arxiv.org/abs/1306.6215
31! -----------------------------------------------------------------------
32! Reference paper for terrestrial plume model:
33! C. Rio and F. Hourdin.
34! A thermal plume model for the convective boundary layer : Representation of cumulus clouds.
35! Journal of the Atmospheric Sciences, 65:407-425, 2008.
36! -----------------------------------------------------------------------
37
38      SUBROUTINE calltherm_interface (ngrid,nlayer,nq, &
39     & tracer,igcm_co2, &
40     & zzlev,zzlay, &
41     & ptimestep,pu,pv,pt,pq,pdu,pdv,pdt,pdq,q2, &
42     & pplay,pplev,pphi,zpopsk, &
43     & pdu_th,pdv_th,pdt_th,pdq_th,lmax,zmaxth,pbl_dtke, &
44     & pdhdif,hfmax,wstar,sensibFlux)
45
46      use comtherm_h
47      use tracer_mod, only: nqmx,noms
48
49      ! SHARED VARIABLES. This needs adaptations in another climate model.
50      ! contains physical constant values such as
51      ! "g" : gravitational acceleration (m.s-2)
52      ! "r" : recuced gas constant (J.K-1.mol-1)
53      ! "cpp" : specific heat of the atmosphere (J.kg-1.K-1)
54      USE comcstfi_h
55
56      implicit none
57
58!--------------------------------------------------------
59! Input Variables
60!--------------------------------------------------------
61
62      INTEGER, INTENT(IN) :: ngrid ! number of horizontal grid points
63      INTEGER, INTENT(IN) :: nlayer ! number of vertical grid points
64      INTEGER, INTENT(IN) :: nq ! number of tracer species
65      REAL, INTENT(IN) :: ptimestep !timestep (s)
66      REAL, INTENT(IN) :: pplev(ngrid,nlayer+1) !intermediate pressure levels (Pa)
67      REAL, INTENT(IN) :: pplay(ngrid,nlayer) !Pressure at the middle of the layers (Pa)
68      REAL, INTENT(IN) :: pphi(ngrid,nlayer) !Geopotential at the middle of the layers (m2s-2)
69      REAL, INTENT(IN) :: pu(ngrid,nlayer),pv(ngrid,nlayer) !u,v components of the wind (ms-1)
70      REAL, INTENT(IN) :: pt(ngrid,nlayer),pq(ngrid,nlayer,nq)!temperature (K) and tracer concentration (kg/kg)
71      REAL, INTENT(IN) :: zzlay(ngrid,nlayer) ! altitude at the middle of the layers
72      REAL, INTENT(IN) :: zzlev(ngrid,nlayer+1) ! altitude at layer boundaries
73      LOGICAL, INTENT(IN) :: tracer ! =.true. if tracers are present and to be transported
74      INTEGER, INTENT(IN) :: igcm_co2 ! index of the CO2 tracer in mixing ratio array
75                                      ! --> 0 if no tracer is CO2 (or no tracer at all)
76                                      ! --> this prepares special treatment for polar night mixing
77                                      !       (see thermcell_main_mars)
78      REAL, INTENT(IN) :: pdu(ngrid,nlayer),pdv(ngrid,nlayer) ! wind velocity change from routines called
79                                                                      ! before thermals du/dt (m/s/s)
80      REAL, INTENT(IN) :: pdq(ngrid,nlayer,nq) ! tracer concentration change from routines called
81                                                     ! before thermals dq/dt (kg/kg/s)
82      REAL, INTENT(IN) :: pdt(ngrid,nlayer) ! temperature change from routines called before thermals dT/dt (K/s)
83      REAL, INTENT(IN) :: q2(ngrid,nlayer+1) ! turbulent kinetic energy
84      REAL, INTENT(IN) :: zpopsk(ngrid,nlayer) ! ratio of pressure at middle of layer to surface pressure,
85                                                   ! to the power r/cp, i.e. zpopsk=(pplay(ig,l)/pplev(ig,1))**rcp
86      REAL, INTENT(IN) :: pdhdif(ngrid,nlayer) ! potential temperature change from turbulent diffusion scheme dT/dt (K/s)
87      REAL, INTENT(IN) :: sensibFlux(ngrid) ! sensible heat flux computed from surface layer scheme
88
89!--------------------------------------------------------
90! Output Variables
91!--------------------------------------------------------
92
93      REAL, INTENT(OUT) :: pdu_th(ngrid,nlayer) ! wind velocity change from thermals du/dt (m/s/s)
94      REAL, INTENT(OUT) :: pdv_th(ngrid,nlayer) ! wind velocity change from thermals dv/dt (m/s/s)
95      REAL, INTENT(OUT) :: pdt_th(ngrid,nlayer) ! temperature change from thermals dT/dt (K/s)
96      REAL, INTENT(OUT) :: pdq_th(ngrid,nlayer,nq) ! tracer change from thermals dq/dt (kg/kg/s)
97      INTEGER, INTENT(OUT) :: lmax(ngrid) ! layer number reacher by thermals in grid point
98      REAL, INTENT(OUT) :: zmaxth(ngrid) ! equivalent to lmax, but in (m), interpolated
99      REAL, INTENT(OUT) :: pbl_dtke(ngrid,nlayer+1) ! turbulent kinetic energy change from thermals dtke/dt
100      REAL, INTENT(OUT) :: wstar(ngrid) ! free convection velocity (m/s)
101
102!--------------------------------------------------------
103! Thermals local variables
104!--------------------------------------------------------
105      REAL zu(ngrid,nlayer), zv(ngrid,nlayer)
106      REAL zt(ngrid,nlayer)
107      REAL d_t_ajs(ngrid,nlayer)
108      REAL d_u_ajs(ngrid,nlayer), d_q_ajs(ngrid,nlayer,nq)
109      REAL d_v_ajs(ngrid,nlayer)
110      REAL fm_therm(ngrid,nlayer+1), entr_therm(ngrid,nlayer)
111      REAL detr_therm(ngrid,nlayer),detrmod(ngrid,nlayer)
112      REAL zw2(ngrid,nlayer+1)
113      REAL fraca(ngrid,nlayer+1),zfraca(ngrid,nlayer+1)
114      REAL q_therm(ngrid,nlayer), pq_therm(ngrid,nlayer,nq)
115      REAL q2_therm(ngrid,nlayer), dq2_therm(ngrid,nlayer)
116      REAL lmax_real(ngrid)
117      REAL masse(ngrid,nlayer)
118
119      INTEGER l,ig,iq,ii(1),k
120      CHARACTER (LEN=20) modname
121
122!--------------------------------------------------------
123! Local variables for sub-timestep
124!--------------------------------------------------------
125
126      REAL d_t_the(ngrid,nlayer), d_q_the(ngrid,nlayer,nq)
127      INTEGER isplit
128      REAL fact
129      REAL zfm_therm(ngrid,nlayer+1),zdt
130      REAL zentr_therm(ngrid,nlayer),zdetr_therm(ngrid,nlayer)
131      REAL zheatFlux(ngrid,nlayer)
132      REAL zheatFlux_down(ngrid,nlayer)
133      REAL zbuoyancyOut(ngrid,nlayer)
134      REAL zbuoyancyEst(ngrid,nlayer)
135      REAL zzw2(ngrid,nlayer+1)
136      REAL zmax(ngrid)
137      INTEGER ndt,limz
138
139!--------------------------------------------------------
140! Diagnostics
141!--------------------------------------------------------
142
143      REAL heatFlux(ngrid,nlayer)
144      REAL heatFlux_down(ngrid,nlayer)
145      REAL buoyancyOut(ngrid,nlayer)
146      REAL buoyancyEst(ngrid,nlayer)
147      REAL hfmax(ngrid),wmax(ngrid)
148      REAL pbl_teta(ngrid),dteta(ngrid,nlayer)
149      REAL rpdhd(ngrid,nlayer)
150      REAL wtdif(ngrid,nlayer),rho(ngrid,nlayer)
151      REAL wtth(ngrid,nlayer)
152
153! **********************************************************************
154! Initializations
155! **********************************************************************
156
157      lmax(:)=0
158      pdu_th(:,:)=0.
159      pdv_th(:,:)=0.
160      pdt_th(:,:)=0.
161      entr_therm(:,:)=0.
162      detr_therm(:,:)=0.
163      q2_therm(:,:)=0.
164      dq2_therm(:,:)=0.
165      pbl_dtke(:,:)=0.
166      fm_therm(:,:)=0.
167      zw2(:,:)=0.
168      fraca(:,:)=0.
169      zfraca(:,:)=0.
170      if (tracer) then
171         pdq_th(:,:,:)=0.
172      end if
173      d_t_ajs(:,:)=0.
174      d_u_ajs(:,:)=0.
175      d_v_ajs(:,:)=0.
176      d_q_ajs(:,:,:)=0.
177      heatFlux(:,:)=0.
178      heatFlux_down(:,:)=0.
179      buoyancyOut(:,:)=0.
180      buoyancyEst(:,:)=0.
181      zmaxth(:)=0.
182      lmax_real(:)=0.
183
184
185! **********************************************************************
186! Preparing inputs for the thermals: increment tendancies
187! from other subroutines called before the thermals model
188! **********************************************************************
189
190       zu(:,:)=pu(:,:)+pdu(:,:)*ptimestep ! u-component of wind velocity
191       zv(:,:)=pv(:,:)+pdv(:,:)*ptimestep ! v-component of wind velocity
192       zt(:,:)=pt(:,:)+pdt(:,:)*ptimestep ! temperature
193
194       pq_therm(:,:,:)=0. ! tracer concentration
195
196       if(qtransport_thermals) then
197          if(tracer) then ! tracer is a logical that is true if tracer must be transported in the GCM physics
198                pq_therm(:,:,:)=pq(:,:,:)+pdq(:,:,:)*ptimestep ! tracer concentration
199          endif
200       endif
201
202
203       IF(dtke_thermals) THEN
204          DO l=1,nlayer
205              q2_therm(:,l)=0.5*(q2(:,l)+q2(:,l+1))
206          ENDDO
207       ENDIF
208
209! **********************************************************************
210! --> CALLTHERM
211! SUB-TIMESTEP LOOP
212! **********************************************************************
213
214         zdt=ptimestep/REAL(nsplit_thermals) !subtimestep
215
216         DO isplit=1,nsplit_thermals !temporal loop on the subtimestep
217
218! Initialization of intermediary variables
219
220         zzw2(:,:)=0.
221         zmax(:)=0.
222         lmax(:)=0
223
224         if (nq .ne. 0 .and. igcm_co2 .ne. 0) then !initialize co2 tracer tendancy
225            d_q_the(:,:,igcm_co2)=0.
226         endif
227
228! CALL to main thermal routine
229             CALL thermcell_main_mars(ngrid,nlayer,nq &
230     &      ,tracer,igcm_co2 &
231     &      ,zdt  &
232     &      ,pplay,pplev,pphi,zzlev,zzlay  &
233     &      ,zu,zv,zt,pq_therm,q2_therm  &
234     &      ,d_t_the,d_q_the  &
235     &      ,zfm_therm,zentr_therm,zdetr_therm,lmax,zmax,limz  &
236     &      ,zzw2,fraca,zpopsk &
237     &      ,zheatFlux,zheatFlux_down &
238     &      ,zbuoyancyOut,zbuoyancyEst)
239
240      fact=1./REAL(nsplit_thermals)
241
242! Update thermals tendancies
243            d_t_the(:,:)=d_t_the(:,:)*ptimestep*fact !temperature
244            if (igcm_co2 .ne. 0) then
245               d_q_the(:,:,igcm_co2)=d_q_the(:,:,igcm_co2)*ptimestep*fact !co2 mass mixing ratio
246            endif
247            zmaxth(:)=zmaxth(:)+zmax(:)*fact !thermals height
248            lmax_real(:)=lmax_real(:)+float(lmax(:))*fact !thermals height index
249            fm_therm(:,:)=fm_therm(:,:)  & !upward mass flux
250     &      +zfm_therm(:,:)*fact
251            entr_therm(:,:)=entr_therm(:,:)  & !entrainment mass flux
252     &       +zentr_therm(:,:)*fact
253            detr_therm(:,:)=detr_therm(:,:)  & !detrainment mass flux
254     &       +zdetr_therm(:,:)*fact
255            zfraca(:,:)=zfraca(:,:) + fraca(:,:)*fact !updraft fractional coverage
256            heatFlux(:,:)=heatFlux(:,:) & !upward heat flux
257     &       +zheatFlux(:,:)*fact
258            heatFlux_down(:,:)=heatFlux_down(:,:) & !downward heat flux
259     &       +zheatFlux_down(:,:)*fact
260            buoyancyOut(:,:)=buoyancyOut(:,:) & !plume final buoyancy
261     &       +zbuoyancyOut(:,:)*fact
262            buoyancyEst(:,:)=buoyancyEst(:,:) & !plume estimated buoyancy used for vertical velocity computation
263     &       +zbuoyancyEst(:,:)*fact
264            zw2(:,:)=zw2(:,:) + zzw2(:,:)*fact !vertical velocity
265
266! Save tendancies
267           d_t_ajs(:,:)=d_t_ajs(:,:)+d_t_the(:,:) !temperature tendancy (delta T)
268            if (igcm_co2 .ne. 0) then
269               d_q_ajs(:,:,igcm_co2)=d_q_ajs(:,:,igcm_co2)+d_q_the(:,:,igcm_co2) !tracer tendancy (delta q)
270            endif
271
272!  Increment temperature and co2 concentration for next pass in subtimestep loop
273            zt(:,:) = zt(:,:) + d_t_the(:,:) !temperature
274            if (igcm_co2 .ne. 0) then
275             pq_therm(:,:,igcm_co2) = &
276     &          pq_therm(:,:,igcm_co2) + d_q_the(:,:,igcm_co2) !co2 tracer
277            endif
278
279
280         ENDDO ! isplit
281!****************************************************************
282
283! Now that we have computed total entrainment and detrainment, we can
284! advect u, v, and q in thermals. (potential temperature and co2 MMR
285! have already been advected in thermcell_main because they are coupled
286! to the determination of the thermals caracteristics). This is done
287! separatly because u,v, and q are not used in thermcell_main for
288! any thermals-related computation : they are purely passive.
289
290! mass of cells
291      do l=1,nlayer
292         masse(:,l)=(pplev(:,l)-pplev(:,l+1))/g
293      enddo
294
295! recompute detrainment mass flux from entrainment and upward mass flux
296! this ensure mass flux conservation
297      detrmod(:,:)=0.
298      do l=1,limz
299         do ig=1,ngrid
300            detrmod(ig,l)=fm_therm(ig,l)-fm_therm(ig,l+1) &
301     &      +entr_therm(ig,l)
302            if (detrmod(ig,l).lt.0.) then
303               entr_therm(ig,l)=entr_therm(ig,l)-detrmod(ig,l)
304               detrmod(ig,l)=0.
305            endif
306         enddo
307      enddo
308
309      ! u component of wind velocity advection in thermals
310      ! result is a derivative (d_u_ajs in m/s/s)
311      ndt=10
312      call thermcell_dqup(ngrid,nlayer,ptimestep                &
313     &      ,fm_therm,entr_therm,detrmod,  &
314     &     masse,zu,d_u_ajs,ndt,limz)
315
316      ! v component of wind velocity advection in thermals
317      ! result is a derivative (d_v_ajs in m/s/s)
318      call thermcell_dqup(ngrid,nlayer,ptimestep    &
319     &       ,fm_therm,entr_therm,detrmod,  &
320     &     masse,zv,d_v_ajs,ndt,limz)
321
322      ! non co2 tracers advection in thermals
323      ! result is a derivative (d_q_ajs in kg/kg/s)
324
325      if (nq .ne. 0.) then
326      DO iq=1,nq
327      if (iq .ne. igcm_co2) then
328      call thermcell_dqup(ngrid,nlayer,ptimestep     &
329     &     ,fm_therm,entr_therm,detrmod,  &
330     &    masse,pq_therm(:,:,iq),d_q_ajs(:,:,iq),ndt,limz)
331      endif
332      ENDDO
333      endif
334
335      ! tke advection in thermals
336      ! result is a tendancy (d_u_ajs in J)
337      if (dtke_thermals) then
338      call thermcell_dqup(ngrid,nlayer,ptimestep     &
339     &     ,fm_therm,entr_therm,detrmod,  &
340     &    masse,q2_therm,dq2_therm,ndt,limz)
341      endif
342
343      ! compute wmax for diagnostics
344      DO ig=1,ngrid
345         wmax(ig)=MAXVAL(zw2(ig,:))
346      ENDDO
347
348! **********************************************************************
349! **********************************************************************
350! **********************************************************************
351! CALLTHERM END
352! **********************************************************************
353! **********************************************************************
354! **********************************************************************
355
356
357! **********************************************************************
358! Preparing outputs
359! **********************************************************************
360
361      do l=1,limz
362        pdu_th(:,l)=d_u_ajs(:,l)
363        pdv_th(:,l)=d_v_ajs(:,l)
364      enddo
365
366           ! if tracers are transported in thermals, update output variables, else these are 0.
367           if(qtransport_thermals) then
368              if(tracer) then
369               do iq=1,nq
370                if (iq .ne. igcm_co2) then
371                  do l=1,limz
372                     pdq_th(:,l,iq)=d_q_ajs(:,l,iq) !non-co2 tracers d_q_ajs are dq/dt (kg/kg/s)
373                  enddo
374                else
375                  do l=1,limz
376                     pdq_th(:,l,iq)=d_q_ajs(:,l,iq)/ptimestep !co2 tracer d_q_ajs is dq (kg/kg)
377                  enddo
378                endif
379               enddo
380              endif
381           endif
382
383           ! if tke is transported in thermals, update output variable, else this is 0.
384           IF(dtke_thermals) THEN
385              DO l=2,nlayer
386                 pbl_dtke(:,l)=0.5*(dq2_therm(:,l-1)+dq2_therm(:,l))
387              ENDDO
388 
389              pbl_dtke(:,1)=0.5*dq2_therm(:,1)
390              pbl_dtke(:,nlayer+1)=0.
391           ENDIF
392
393           ! update output variable for temperature. d_t_ajs is delta T in (K), pdt_th is dT/dt in (K/s)
394           do l=1,limz
395              pdt_th(:,l)=d_t_ajs(:,l)/ptimestep
396           enddo
397
398
399! **********************************************************************
400! SURFACE LAYER INTERFACE
401! Compute the free convection velocity w* scale for surface layer gustiness
402! speed parameterization. The computed value of w* will be used at the next
403! timestep to modify surface-atmosphere exchange fluxes, because the surface
404! layer scheme and diffusion are called BEFORE the thermals. (outside of these
405! routines)
406! **********************************************************************
407
408! Potential temperature gradient
409
410      dteta(:,nlayer)=0.
411      DO l=1,nlayer-1
412         DO ig=1, ngrid
413            dteta(ig,l) = ((zt(ig,l+1)-zt(ig,l))/zpopsk(ig,l))          &
414     &              /(zzlay(ig,l+1)-zzlay(ig,l))
415         ENDDO
416      ENDDO
417
418! Computation of the PBL mixed layer temperature
419
420      DO ig=1, ngrid
421         ii=MINLOC(abs(dteta(ig,1:lmax(ig))))
422         pbl_teta(ig) = zt(ig,ii(1))/zpopsk(ig,ii(1))
423      ENDDO
424
425! In order to have an accurate w*, we must add the heat flux from the
426! diffusion scheme to the computation of the maximum heat flux hfmax
427! Here pdhdif is the potential temperature change from the diffusion
428! scheme (Mellor and Yamada, see paper section 6, paragraph 57)
429
430! compute rho as it is after the diffusion
431
432      rho(:,:)=pplay(:,:)                                               &
433     & /(r*(pt(:,:)+pdhdif(:,:)*zpopsk(:,:)*ptimestep))
434
435! integrate -rho*pdhdif
436
437      rpdhd(:,:)=0.
438
439      DO ig=1,ngrid
440       DO l=1,lmax(ig)
441        rpdhd(ig,l)=0.
442        DO k=1,l
443         rpdhd(ig,l)=rpdhd(ig,l)-rho(ig,k)*pdhdif(ig,k)*                &
444     & (zzlev(ig,k+1)-zzlev(ig,k))
445        ENDDO
446        rpdhd(ig,l)=rpdhd(ig,l)-sensibFlux(ig)/cpp
447       ENDDO
448      ENDDO
449
450! compute w'theta' (vertical turbulent flux of temperature) from
451! the diffusion scheme
452
453      wtdif(:,:)=rpdhd(:,:)/rho(:,:)
454
455! Now we compute the contribution of the thermals to w'theta':
456! compute rho as it is after the thermals
457
458      rho(:,:)=pplay(:,:)/(r*(zt(:,:)))
459
460! integrate -rho*pdhdif
461
462      DO ig=1,ngrid
463       DO l=1,lmax(ig)
464        rpdhd(ig,l)=0.
465        DO k=1,l
466         rpdhd(ig,l)=rpdhd(ig,l)-rho(ig,k)*(pdt_th(ig,k)/zpopsk(ig,k))* &
467     & (zzlev(ig,k+1)-zzlev(ig,k))
468        ENDDO
469        rpdhd(ig,l)=rpdhd(ig,l)+                                        &
470     &    rho(ig,1)*(heatFlux(ig,1)+heatFlux_down(ig,1))
471       ENDDO
472      ENDDO
473      rpdhd(:,nlayer)=0.
474
475! compute w'teta' from thermals
476
477      wtth(:,:)=rpdhd(:,:)/rho(:,:)
478
479! Add vertical turbulent heat fluxes from the thermals and the diffusion scheme
480! and compute the maximum
481
482      DO ig=1,ngrid
483        hfmax(ig)=MAXVAL(wtth(ig,:)+wtdif(ig,:))
484      ENDDO
485
486! Finally we can compute the free convection velocity scale
487! We follow Spiga et. al 2010 (QJRMS)
488! ------------
489
490      DO ig=1, ngrid
491         IF (zmax(ig) .gt. 0.) THEN
492            wstar(ig)=(g*zmaxth(ig)*hfmax(ig)/pbl_teta(ig))**(1./3.)
493         ELSE
494            wstar(ig)=0.
495         ENDIF
496      ENDDO
497
498       END
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