source: lmdz_wrf/trunk/WRFV3/phys/module_bl_gwdo.F @ 354

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1! WRf:model_layer:physics
2!
3!
4!
5!
6!
7module module_bl_gwdo
8contains
9!
10!-------------------------------------------------------------------
11!
12   subroutine gwdo(u3d,v3d,t3d,qv3d,p3d,p3di,pi3d,z, &
13                  rublten,rvblten, &
14                  dtaux3d,dtauy3d,dusfcg,dvsfcg, &
15                  var2d,oc12d,oa2d1,oa2d2,oa2d3,oa2d4,ol2d1,ol2d2,ol2d3,ol2d4, &
16                  znu,znw,mut,p_top, &
17                  cp,g,rd,rv,ep1,pi, &
18                  dt,dx,kpbl2d,itimestep, &
19                  ids,ide, jds,jde, kds,kde, &
20                  ims,ime, jms,jme, kms,kme, &
21                  its,ite, jts,jte, kts,kte)
22!-------------------------------------------------------------------
23      implicit none
24!------------------------------------------------------------------------------
25!
26!-- u3d 3d u-velocity interpolated to theta points (m/s)
27!-- v3d 3d v-velocity interpolated to theta points (m/s)
28!-- t3d temperature (k)
29!-- qv3d 3d water vapor mixing ratio (kg/kg)
30!-- p3d 3d pressure (pa)
31!-- p3di 3d pressure (pa) at interface level
32!-- pi3d 3d exner function (dimensionless)
33!-- rublten u tendency due to
34! pbl parameterization (m/s/s)
35!-- rvblten v tendency due to
36!-- cp heat capacity at constant pressure for dry air (j/kg/k)
37!-- g acceleration due to gravity (m/s^2)
38!-- rd gas constant for dry air (j/kg/k)
39!-- z height above sea level (m)
40!-- rv gas constant for water vapor (j/kg/k)
41!-- dt time step (s)
42!-- dx model grid interval (m)
43!-- ep1 constant for virtual temperature (r_v/r_d - 1) (dimensionless)
44!-- ids start index for i in domain
45!-- ide end index for i in domain
46!-- jds start index for j in domain
47!-- jde end index for j in domain
48!-- kds start index for k in domain
49!-- kde end index for k in domain
50!-- ims start index for i in memory
51!-- ime end index for i in memory
52!-- jms start index for j in memory
53!-- jme end index for j in memory
54!-- kms start index for k in memory
55!-- kme end index for k in memory
56!-- its start index for i in tile
57!-- ite end index for i in tile
58!-- jts start index for j in tile
59!-- jte end index for j in tile
60!-- kts start index for k in tile
61!-- kte end index for k in tile
62!-------------------------------------------------------------------
63!
64  integer, intent(in ) :: ids,ide, jds,jde, kds,kde, &
65                                     ims,ime, jms,jme, kms,kme, &
66                                     its,ite, jts,jte, kts,kte
67  integer, intent(in ) :: itimestep
68!
69  real, intent(in ) :: dt,dx,cp,g,rd,rv,ep1,pi
70!
71  real, dimension( ims:ime, kms:kme, jms:jme ) , &
72            intent(in ) :: qv3d, &
73                                                                          p3d, &
74                                                                         pi3d, &
75                                                                          t3d, &
76                                                                             z
77  real, dimension( ims:ime, kms:kme, jms:jme ) , &
78            intent(in ) :: p3di
79!
80  real, dimension( ims:ime, kms:kme, jms:jme ) , &
81            intent(inout) :: rublten, &
82                                                                      rvblten
83  real, dimension( ims:ime, kms:kme, jms:jme ) , &
84            intent(inout) :: dtaux3d, &
85                                                                      dtauy3d
86!
87  real, dimension( ims:ime, kms:kme, jms:jme ) , &
88             intent(in ) :: u3d, &
89                                                                          v3d
90!
91  integer, dimension( ims:ime, jms:jme ) , &
92             intent(in ) :: kpbl2d
93  real, dimension( ims:ime, jms:jme ) , &
94             intent(inout ) :: dusfcg, &
95                                                                       dvsfcg
96!
97  real, dimension( ims:ime, jms:jme ) , &
98             intent(in ) :: var2d, &
99                                                                        oc12d, &
100                                                      oa2d1,oa2d2,oa2d3,oa2d4, &
101                                                      ol2d1,ol2d2,ol2d3,ol2d4
102!
103  real, dimension( ims:ime, jms:jme ) , &
104             optional , &
105             intent(in ) :: mut
106!
107  real, dimension( kms:kme ) , &
108             optional , &
109             intent(in ) :: znu, &
110                                                                          znw
111!
112  real, optional, intent(in ) :: p_top
113!
114!local
115!
116  real, dimension( its:ite, kts:kte ) :: delprsi, &
117                                                                          pdh
118  real, dimension( its:ite, kts:kte+1 ) :: pdhi
119  real, dimension( its:ite, 4 ) :: oa4, &
120                                                                          ol4
121  integer :: i,j,k,kdt
122!
123   do j = jts,jte
124      if(present(mut))then
125! For ARW we will replace p and p8w with dry hydrostatic pressure
126        do k = kts,kte+1
127          do i = its,ite
128             if(k.le.kte)pdh(i,k) = mut(i,j)*znu(k) + p_top
129             pdhi(i,k) = mut(i,j)*znw(k) + p_top
130          enddo
131        enddo
132      else
133        do k = kts,kte+1
134          do i = its,ite
135             if(k.le.kte)pdh(i,k) = p3d(i,k,j)
136             pdhi(i,k) = p3di(i,k,j)
137          enddo
138        enddo
139      endif
140!
141      do k = kts,kte
142        do i = its,ite
143          delprsi(i,k) = pdhi(i,k)-pdhi(i,k+1)
144        enddo
145      enddo
146        do i = its,ite
147            oa4(i,1) = oa2d1(i,j)
148            oa4(i,2) = oa2d2(i,j)
149            oa4(i,3) = oa2d3(i,j)
150            oa4(i,4) = oa2d4(i,j)
151            ol4(i,1) = ol2d1(i,j)
152            ol4(i,2) = ol2d2(i,j)
153            ol4(i,3) = ol2d3(i,j)
154            ol4(i,4) = ol2d4(i,j)
155        enddo
156      call gwdo2d(dudt=rublten(ims,kms,j),dvdt=rvblten(ims,kms,j) &
157              ,dtaux2d=dtaux3d(ims,kms,j),dtauy2d=dtauy3d(ims,kms,j) &
158              ,u1=u3d(ims,kms,j),v1=v3d(ims,kms,j) &
159              ,t1=t3d(ims,kms,j),q1=qv3d(ims,kms,j) &
160              ,prsi=pdhi(its,kts),del=delprsi(its,kts) &
161              ,prsl=pdh(its,kts),prslk=pi3d(ims,kms,j) &
162              ,zl=z(ims,kms,j),rcl=1.0 &
163              ,dusfc=dusfcg(ims,j),dvsfc=dvsfcg(ims,j) &
164              ,var=var2d(ims,j),oc1=oc12d(ims,j) &
165              ,oa4=oa4,ol4=ol4 &
166              ,g=g,cp=cp,rd=rd,rv=rv,fv=ep1,pi=pi &
167              ,dxmeter=dx,deltim=dt &
168              ,kpbl=kpbl2d(ims,j),kdt=itimestep,lat=j &
169              ,ids=ids,ide=ide, jds=jds,jde=jde, kds=kds,kde=kde &
170              ,ims=ims,ime=ime, jms=jms,jme=jme, kms=kms,kme=kme &
171              ,its=its,ite=ite, jts=jts,jte=jte, kts=kts,kte=kte )
172   enddo
173!
174!
175   end subroutine gwdo
176!
177!-------------------------------------------------------------------
178!
179!
180!
181!
182   subroutine gwdo2d(dudt,dvdt,dtaux2d,dtauy2d, &
183                    u1,v1,t1,q1, &
184                    prsi,del,prsl,prslk,zl,rcl, &
185                    var,oc1,oa4,ol4,dusfc,dvsfc, &
186                    g,cp,rd,rv,fv,pi,dxmeter,deltim,kpbl,kdt,lat, &
187                    ids,ide, jds,jde, kds,kde, &
188                    ims,ime, jms,jme, kms,kme, &
189                    its,ite, jts,jte, kts,kte)
190!-------------------------------------------------------------------
191!
192! this code handles the time tendencies of u v due to the effect of mountain
193! induced gravity wave drag from sub-grid scale orography. this routine
194! not only treats the traditional upper-level wave breaking due to mountain
195! variance (alpert 1988), but also the enhanced lower-tropospheric wave
196! breaking due to mountain convexity and asymmetry (kim and arakawa 1995).
197! thus, in addition to the terrain height data in a model grid gox,
198! additional 10-2d topographic statistics files are needed, including
199! orographic standard deviation (var), convexity (oc1), asymmetry (oa4)
200! and ol (ol4). these data sets are prepared based on the 30 sec usgs orography
201! hong (1999). the current scheme was implmented as in hong et al.(2008)
202!
203! coded by song-you hong and young-joon kim and implemented by song-you hong
204!
205! references:
206! hong et al. (2008), wea. and forecasting
207! kim and arakawa (1995), j. atmos. sci.
208! alpet et al. (1988), NWP conference.
209! hong (1999), NCEP office note 424.
210!
211! notice : comparible or lower resolution orography files than model resolution
212! are desirable in preprocess (wps) to prevent weakening of the drag
213!-------------------------------------------------------------------
214!
215! input
216! dudt (ims:ime,kms:kme) non-lin tendency for u wind component
217! dvdt (ims:ime,kms:kme) non-lin tendency for v wind component
218! u1(ims:ime,kms:kme) zonal wind / sqrt(rcl) m/sec at t0-dt
219! v1(ims:ime,kms:kme) meridional wind / sqrt(rcl) m/sec at t0-dt
220! t1(ims:ime,kms:kme) temperature deg k at t0-dt
221! q1(ims:ime,kms:kme) specific humidity at t0-dt
222!
223! rcl a scaling factor = reciprocal of square of cos(lat)
224! for mrf gsm. rcl=1 if u1 and v1 are wind components.
225! deltim time step secs
226! del(kts:kte) positive increment of pressure across layer (pa)
227!
228! output
229! dudt, dvdt wind tendency due to gwdo
230!
231!-------------------------------------------------------------------
232   implicit none
233!-------------------------------------------------------------------
234   integer :: kdt,lat,latd,lond, &
235                            ids,ide, jds,jde, kds,kde, &
236                            ims,ime, jms,jme, kms,kme, &
237                            its,ite, jts,jte, kts,kte
238!
239   real :: g,rd,rv,fv,cp,pi,dxmeter,deltim,rcl
240   real :: dudt(ims:ime,kms:kme),dvdt(ims:ime,kms:kme), &
241                            dtaux2d(ims:ime,kms:kme),dtauy2d(ims:ime,kms:kme), &
242                            u1(ims:ime,kms:kme),v1(ims:ime,kms:kme), &
243                            t1(ims:ime,kms:kme),q1(ims:ime,kms:kme), &
244                            zl(ims:ime,kms:kme),prslk(ims:ime,kms:kme)
245   real :: prsl(its:ite,kts:kte),prsi(its:ite,kts:kte+1), &
246                            del(its:ite,kts:kte)
247   real :: oa4(its:ite,4),ol4(its:ite,4)
248!
249   integer :: kpbl(ims:ime)
250   real :: var(ims:ime),oc1(ims:ime), &
251                            dusfc(ims:ime),dvsfc(ims:ime)
252! critical richardson number for wave breaking : ! larger drag with larger value
253!
254   real,parameter :: ric = 0.25
255!
256   real,parameter :: dw2min = 1.
257   real,parameter :: rimin = -100.
258   real,parameter :: bnv2min = 1.0e-5
259   real,parameter :: efmin = 0.0
260   real,parameter :: efmax = 10.0
261   real,parameter :: xl = 4.0e4
262   real,parameter :: critac = 1.0e-5
263   real,parameter :: gmax = 1.
264   real,parameter :: veleps = 1.0
265   real,parameter :: factop = 0.5
266   real,parameter :: frc = 1.0
267   real,parameter :: ce = 0.8
268   real,parameter :: cg = 0.5
269!
270! local variables
271!
272   integer :: i,k,lcap,lcapp1,nwd,idir,kpblmin,kpblmax, &
273                            klcap,kp1,ikount,kk
274!
275   real :: rcs,rclcs,csg,fdir,cleff,cs,rcsks, &
276                            wdir,ti,rdz,temp,tem2,dw2,shr2,bvf2,rdelks, &
277                            wtkbj,coefm,tem,gfobnv,hd,fro,rim,temc,tem1,efact, &
278                            temv,dtaux,dtauy
279!
280   logical :: ldrag(its:ite),icrilv(its:ite), &
281                            flag(its:ite),kloop1(its:ite)
282!
283   real :: taub(its:ite),taup(its:ite,kts:kte+1), &
284                            xn(its:ite),yn(its:ite), &
285                            ubar(its:ite),vbar(its:ite), &
286                            fr(its:ite),ulow(its:ite), &
287                            rulow(its:ite),bnv(its:ite), &
288                            oa(its:ite),ol(its:ite), &
289                            roll(its:ite),dtfac(its:ite), &
290                            brvf(its:ite),xlinv(its:ite), &
291                            delks(its:ite),delks1(its:ite), &
292                            bnv2(its:ite,kts:kte),usqj(its:ite,kts:kte), &
293                            taud(its:ite,kts:kte),ro(its:ite,kts:kte), &
294                            vtk(its:ite,kts:kte),vtj(its:ite,kts:kte), &
295                            zlowtop(its:ite),velco(its:ite,kts:kte-1)
296!
297   integer :: kbl(its:ite),klowtop(its:ite), &
298                            lowlv(its:ite)
299!
300   logical :: iope
301   integer,parameter :: mdir=8
302   integer :: nwdir(mdir)
303   data nwdir/6,7,5,8,2,3,1,4/
304!
305! initialize local variables
306!
307   kbl=0 ; klowtop=0 ; lowlv=0
308!
309!---- constants
310!
311   rcs = sqrt(rcl)
312   cs = 1. / sqrt(rcl)
313   csg = cs * g
314   lcap = kte
315   lcapp1 = lcap + 1
316   fdir = mdir / (2.0*pi)
317!
318!
319!!!!!!! cleff (subgrid mountain scale ) is highly tunable parameter
320!!!!!!! the bigger (smaller) value produce weaker (stronger) wave drag
321!
322   cleff = max(dxmeter,50.e3)
323!
324! initialize!!
325!
326   dtaux = 0.0
327   dtauy = 0.0
328   do k = kts,kte
329     do i = its,ite
330       usqj(i,k) = 0.0
331       bnv2(i,k) = 0.0
332       vtj(i,k) = 0.0
333       vtk(i,k) = 0.0
334       taup(i,k) = 0.0
335       taud(i,k) = 0.0
336       dtaux2d(i,k)= 0.0
337       dtauy2d(i,k)= 0.0
338     enddo
339   enddo
340   do i = its,ite
341     taup(i,kte+1) = 0.0
342     xlinv(i) = 1.0/xl
343   enddo
344!
345   do k = kts,kte
346     do i = its,ite
347       vtj(i,k) = t1(i,k) * (1.+fv*q1(i,k))
348       vtk(i,k) = vtj(i,k) / prslk(i,k)
349       ro(i,k) = 1./rd * prsl(i,k) / vtj(i,k) ! density kg/m**3
350     enddo
351   enddo
352!
353   do i = its,ite
354     zlowtop(i) = 2. * var(i)
355   enddo
356!
357!--- determine new reference level > 2*var
358!
359   do i = its,ite
360     kloop1(i) = .true.
361   enddo
362   do k = kts+1,kte
363     do i = its,ite
364       if(kloop1(i).and.zl(i,k)-zl(i,1).ge.zlowtop(i)) then
365         klowtop(i) = k+1
366         kloop1(i) = .false.
367       endif
368     enddo
369   enddo
370!
371   kpblmax = 2
372   do i = its,ite
373     kbl(i) = max(2, kpbl(i))
374     kbl(i) = max(kbl(i), klowtop(i))
375     delks(i) = 1.0 / (prsi(i,1) - prsi(i,kbl(i)))
376     ubar (i) = 0.0
377     vbar (i) = 0.0
378     taup(i,1) = 0.0
379     oa(i) = 0.0
380     kpblmax = max(kpblmax,kbl(i))
381     flag(i) = .true.
382     lowlv(i) = 2
383   enddo
384   kpblmax = min(kpblmax+1,kte-1)
385!
386! compute low level averages within pbl
387!
388   do k = kts,kpblmax
389     do i = its,ite
390       if (k.lt.kbl(i)) then
391         rcsks = rcs * del(i,k) * delks(i)
392         ubar(i) = ubar(i) + rcsks * u1(i,k) ! pbl u mean
393         vbar(i) = vbar(i) + rcsks * v1(i,k) ! pbl v mean
394       endif
395     enddo
396   enddo
397!
398! figure out low-level horizontal wind direction
399!
400! nwd 1 2 3 4 5 6 7 8
401! wd w s sw nw e n ne se
402!
403   do i = its,ite
404     wdir = atan2(ubar(i),vbar(i)) + pi
405     idir = mod(nint(fdir*wdir),mdir) + 1
406     nwd = nwdir(idir)
407     oa(i) = (1-2*int( (nwd-1)/4 )) * oa4(i,mod(nwd-1,4)+1)
408     ol(i) = ol4(i,mod(nwd-1,4)+1)
409   enddo
410!
411   kpblmin = kte
412   do i = its,ite
413     kpblmin = min(kpblmin, kbl(i))
414   enddo
415!
416   do i = its,ite
417     if (oa(i).le.0.0) kbl(i) = kpbl(i) + 1
418   enddo
419!
420   do i = its,ite
421     delks(i) = 1.0 / (prsi(i,1) - prsi(i,kbl(i)))
422     delks1(i) = 1.0 / (prsl(i,1) - prsl(i,kbl(i)))
423   enddo
424!
425!--- saving richardson number in usqj for migwdi
426!
427   do k = kts,kte-1
428     do i = its,ite
429       ti = 2.0 / (t1(i,k)+t1(i,k+1))
430       rdz = 1./(zl(i,k+1) - zl(i,k))
431       tem1 = u1(i,k) - u1(i,k+1)
432       tem2 = v1(i,k) - v1(i,k+1)
433       dw2 = rcl*(tem1*tem1 + tem2*tem2)
434       shr2 = max(dw2,dw2min) * rdz * rdz
435       bvf2 = g*(g/cp+rdz*(vtj(i,k+1)-vtj(i,k))) * ti
436       usqj(i,k) = max(bvf2/shr2,rimin)
437       bnv2(i,k) = 2*g*rdz*(vtk(i,k+1)-vtk(i,k))/(vtk(i,k+1)+vtk(i,k))
438       bnv2(i,k) = max( bnv2(i,k), bnv2min )
439     enddo
440   enddo
441!
442!-----initialize arrays
443!
444   do i = its,ite
445     xn(i) = 0.0
446     yn(i) = 0.0
447     ubar (i) = 0.0
448     vbar (i) = 0.0
449     roll (i) = 0.0
450     taub (i) = 0.0
451     ulow (i) = 0.0
452     dtfac(i) = 1.0
453     ldrag(i) = .false.
454     icrilv(i) = .false. ! initialize critical level control vector
455   enddo
456!
457!---- compute low level averages
458!---- (u,v)*cos(lat) use uv=(u1,v1) which is wind at t0-1
459!---- use rcs=1/cos(lat) to get wind field
460!
461   do k = 1,kpblmax
462     do i = its,ite
463       if (k .lt. kbl(i)) then
464         rdelks = del(i,k) * delks(i)
465         rcsks = rcs * rdelks
466         ubar(i) = ubar(i) + rcsks * u1(i,k) ! u mean
467         vbar(i) = vbar(i) + rcsks * v1(i,k) ! v mean
468         roll(i) = roll(i) + rdelks * ro(i,k) ! ro mean
469       endif
470     enddo
471   enddo
472!
473!----compute the "low level" or 1/3 wind magnitude (m/s)
474!
475   do i = its,ite
476     ulow(i) = max(sqrt(ubar(i)*ubar(i) + vbar(i)*vbar(i)), 1.0)
477     rulow(i) = 1./ulow(i)
478   enddo
479!
480   do k = kts,kte-1
481     do i = its,ite
482       velco(i,k) = (0.5*rcs) * ((u1(i,k)+u1(i,k+1)) * ubar(i) &
483                                + (v1(i,k)+v1(i,k+1)) * vbar(i))
484       velco(i,k) = velco(i,k) * rulow(i)
485       if ((velco(i,k).lt.veleps) .and. (velco(i,k).gt.0.)) then
486         velco(i,k) = veleps
487       endif
488     enddo
489   enddo
490!
491! no drag when critical level in the base layer
492!
493   do i = its,ite
494     ldrag(i) = velco(i,1).le.0.
495   enddo
496!
497   do k = kts+1,kpblmax-1
498     do i = its,ite
499       if (k .lt. kbl(i)) ldrag(i) = ldrag(i).or. velco(i,k).le.0.
500     enddo
501   enddo
502!
503! no drag when bnv2.lt.0
504!
505   do k = kts,kpblmax-1
506     do i = its,ite
507       if (k .lt. kbl(i)) ldrag(i) = ldrag(i).or. bnv2(i,k).lt.0.
508     enddo
509   enddo
510!
511!-----the low level weighted average ri is stored in usqj(1,1; im)
512!-----the low level weighted average n**2 is stored in bnv2(1,1; im)
513!---- this is called bnvl2 in phys_gwd_alpert_sub not bnv2
514!---- rdelks (del(k)/delks) vert ave factor so we can * instead of /
515!
516   do i = its,ite
517     wtkbj = (prsl(i,1)-prsl(i,2)) * delks1(i)
518     bnv2(i,1) = wtkbj * bnv2(i,1)
519     usqj(i,1) = wtkbj * usqj(i,1)
520   enddo
521!
522   do k = kts+1,kpblmax-1
523     do i = its,ite
524       if (k .lt. kbl(i)) then
525         rdelks = (prsl(i,k)-prsl(i,k+1)) * delks1(i)
526         bnv2(i,1) = bnv2(i,1) + bnv2(i,k) * rdelks
527         usqj(i,1) = usqj(i,1) + usqj(i,k) * rdelks
528       endif
529     enddo
530   enddo
531!
532   do i = its,ite
533     ldrag(i) = ldrag(i) .or. bnv2(i,1).le.0.0
534     ldrag(i) = ldrag(i) .or. ulow(i).eq.1.0
535     ldrag(i) = ldrag(i) .or. var(i) .le. 0.0
536   enddo
537!
538! ----- set all ri low level values to the low level value
539!
540   do k = kts+1,kpblmax-1
541     do i = its,ite
542       if (k .lt. kbl(i)) usqj(i,k) = usqj(i,1)
543     enddo
544   enddo
545!
546   do i = its,ite
547     if (.not.ldrag(i)) then
548       bnv(i) = sqrt( bnv2(i,1) )
549       fr(i) = bnv(i) * rulow(i) * var(i)
550       xn(i) = ubar(i) * rulow(i)
551       yn(i) = vbar(i) * rulow(i)
552     endif
553   enddo
554!
555! compute the base level stress and store it in taub
556! calculate enhancement factor, number of mountains & aspect
557! ratio const. use simplified relationship between standard
558! deviation & critical hgt
559!
560   do i = its,ite
561     if (.not. ldrag(i)) then
562       efact = (oa(i) + 2.) ** (ce*fr(i)/frc)
563       efact = min( max(efact,efmin), efmax )
564       coefm = (1. + ol(i)) ** (oa(i)+1.)
565       xlinv(i) = coefm / cleff
566       tem = fr(i) * fr(i) * oc1(i)
567       gfobnv = gmax * tem / ((tem + cg)*bnv(i))
568       taub(i) = xlinv(i) * roll(i) * ulow(i) * ulow(i) &
569                * ulow(i) * gfobnv * efact
570     else
571       taub(i) = 0.0
572       xn(i) = 0.0
573       yn(i) = 0.0
574     endif
575   enddo
576!
577! now compute vertical structure of the stress.
578!
579!----set up bottom values of stress
580!
581   do k = kts,kpblmax
582     do i = its,ite
583       if (k .le. kbl(i)) taup(i,k) = taub(i)
584     enddo
585   enddo
586!
587   do k = kpblmin, kte-1 ! vertical level k loop!
588     kp1 = k + 1
589     do i = its,ite
590!
591!-----unstablelayer if ri < ric
592!-----unstable layer if upper air vel comp along surf vel <=0 (crit lay)
593!---- at (u-c)=0. crit layer exists and bit vector should be set (.le.)
594!
595       if (k .ge. kbl(i)) then
596         icrilv(i) = icrilv(i) .or. ( usqj(i,k) .lt. ric) &
597                               .or. (velco(i,k) .le. 0.0)
598         brvf(i) = max(bnv2(i,k),bnv2min) ! brunt-vaisala frequency squared
599         brvf(i) = sqrt(brvf(i)) ! brunt-vaisala frequency
600       endif
601     enddo
602!
603     do i = its,ite
604       if (k .ge. kbl(i) .and. (.not. ldrag(i))) then
605         if (.not.icrilv(i) .and. taup(i,k) .gt. 0.0 ) then
606           temv = 1.0 / velco(i,k)
607           tem1 = xlinv(i)*(ro(i,kp1)+ro(i,k))*brvf(i)*velco(i,k)*0.5
608           hd = sqrt(taup(i,k) / tem1)
609           fro = brvf(i) * hd * temv
610!
611! rim is the minimum-richardson number by shutts (1985)
612!
613           tem2 = sqrt(usqj(i,k))
614           tem = 1. + tem2 * fro
615           rim = usqj(i,k) * (1.-fro) / (tem * tem)
616!
617! check stability to employ the 'saturation hypothesis'
618! of lindzen (1981) except at tropospheric downstream regions
619!
620           if (rim .le. ric) then ! saturation hypothesis!
621             if ((oa(i) .le. 0. .or. kp1 .ge. lowlv(i) )) then
622               temc = 2.0 + 1.0 / tem2
623               hd = velco(i,k) * (2.*sqrt(temc)-temc) / brvf(i)
624               taup(i,kp1) = tem1 * hd * hd
625             endif
626           else ! no wavebreaking!
627             taup(i,kp1) = taup(i,k)
628           endif
629         endif
630       endif
631     enddo
632   enddo
633!
634   if(lcap.lt.kte) then
635     do klcap = lcapp1,kte
636       do i = its,ite
637         taup(i,klcap) = prsi(i,klcap) / prsi(i,lcap) * taup(i,lcap)
638       enddo
639     enddo
640   endif
641!
642! calculate - (g)*d(tau)/d(pressure) and deceleration terms dtaux, dtauy
643!
644   do k = kts,kte
645     do i = its,ite
646       taud(i,k) = 1. * (taup(i,k+1) - taup(i,k)) * csg / del(i,k)
647     enddo
648   enddo
649!
650!------limit de-acceleration (momentum deposition ) at top to 1/2 value
651!------the idea is some stuff must go out the 'top'
652!
653   do klcap = lcap,kte
654     do i = its,ite
655       taud(i,klcap) = taud(i,klcap) * factop
656     enddo
657   enddo
658!
659!------if the gravity wave drag would force a critical line
660!------in the lower ksmm1 layers during the next deltim timestep,
661!------then only apply drag until that critical line is reached.
662!
663   do k = kts,kpblmax-1
664     do i = its,ite
665       if (k .le. kbl(i)) then
666         if(taud(i,k).ne.0.) &
667         dtfac(i) = min(dtfac(i),abs(velco(i,k) &
668                   /(deltim*rcs*taud(i,k))))
669       endif
670     enddo
671   enddo
672!
673   do i = its,ite
674     dusfc(i) = 0.
675     dvsfc(i) = 0.
676   enddo
677!
678   do k = kts,kte
679     do i = its,ite
680       taud(i,k) = taud(i,k) * dtfac(i)
681       dtaux = taud(i,k) * xn(i)
682       dtauy = taud(i,k) * yn(i)
683       dtaux2d(i,k) = dtaux
684       dtauy2d(i,k) = dtauy
685       dudt(i,k) = dtaux + dudt(i,k)
686       dvdt(i,k) = dtauy + dvdt(i,k)
687       dusfc(i) = dusfc(i) + dtaux * del(i,k)
688       dvsfc(i) = dvsfc(i) + dtauy * del(i,k)
689     enddo
690   enddo
691!
692   do i = its,ite
693     dusfc(i) = (-1./g*rcs) * dusfc(i)
694     dvsfc(i) = (-1./g*rcs) * dvsfc(i)
695   enddo
696!
697   return
698   end subroutine gwdo2d
699!-------------------------------------------------------------------
700end module module_bl_gwdo
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