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prandtl_fluxes.f90 @ 114

Last change on this file since 114 was 110, checked in by raasch, 17 years ago

New:
---
Allows runs for a coupled atmosphere-ocean LES,
coupling frequency is controlled by new d3par-parameter dt_coupling,
the coupling mode (atmosphere_to_ocean or ocean_to_atmosphere) for the
respective processes is read from environment variable coupling_mode,
which is set by the mpiexec-command,
communication between the two models is done using the intercommunicator
comm_inter,
local files opened by the ocean model get the additional suffic "_O".
Assume saturation at k=nzb_s_inner(j,i) for atmosphere coupled to ocean.

A momentum flux can be set as top boundary condition using the new
inipar parameter top_momentumflux_u|v.

Non-cyclic boundary conditions can be used along all horizontal directions.

Quantities w*p* and w"e can be output as vertical profiles.

Initial profiles are reset to constant profiles in case that initializing_actions /= 'set_constant_profiles'. (init_rankine)

Optionally calculate km and kh from initial TKE e_init.

Changed:

Remaining variables iran changed to iran_part (advec_particles, init_particles).

In case that the presure solver is not called for every Runge-Kutta substep
(call_psolver_at_all_substeps = .F.), it is called after the first substep
instead of the last. In that case, random perturbations are also added to the
velocity field after the first substep.

Initialization of km,kh = 0.00001 for ocean = .T. (for ocean = .F. it remains 0.01).

Allow data_output_pr= q, wq, w"q", w*q* for humidity = .T. (instead of cloud_physics = .T.).

Errors:

Bugs from code parts for non-cyclic boundary conditions are removed: loops for
u and v are starting from index nxlu, nysv, respectively. The radiation boundary
condition is used for every Runge-Kutta substep. Velocity phase speeds for
the radiation boundary conditions are calculated for the first Runge-Kutta
substep only and reused for the further substeps. New arrays c_u, c_v, and c_w
are defined for this purpose. Several index errors are removed from the
radiation boundary condition code parts. Upper bounds for calculating
u_0 and v_0 (in production_e) are nxr+1 and nyn+1 because otherwise these
values are not available in case of non-cyclic boundary conditions.

+dots_num_palm in module user, +module netcdf_control in user_init (both in user_interface)

Bugfix: wrong sign removed from the buoyancy production term in the case use_reference = .T. (production_e)

Bugfix: Error message concerning output of particle concentration (pc) modified (check_parameters).

Bugfix: Rayleigh damping for ocean fixed.

Property svn:keywords set to Id

File size: 14.2 KB

Line
1	SUBROUTINE prandtl_fluxes
2
3	!------------------------------------------------------------------------------!
4	! Actual revisions:
5	! -----------------
6	!
7	!
8	! Former revisions:
9	! -----------------
10	! $Id: prandtl_fluxes.f90 110 2007-10-05 05:13:14Z raasch $
11	!
12	! 108 2007-08-24 15:10:38Z letzel
13	! assume saturation at k=nzb_s_inner(j,i) for atmosphere coupled to ocean
14	!
15	! 75 2007-03-22 09:54:05Z raasch
16	! moisture renamed humidity
17	!
18	! RCS Log replace by Id keyword, revision history cleaned up
19	!
20	! Revision 1.19 2006/04/26 12:24:35 raasch
21	! +OpenMP directives and optimization (array assignments replaced by DO loops)
22	!
23	! Revision 1.1 1998/01/23 10:06:06 raasch
24	! Initial revision
25	!
26	!
27	! Description:
28	! ------------
29	! Diagnostic computation of vertical fluxes in the Prandtl layer from the
30	! values of the variables at grid point k=1
31	!------------------------------------------------------------------------------!
32
33	USE arrays_3d
34	USE control_parameters
35	USE grid_variables
36	USE indices
37
38	IMPLICIT NONE
39
40	INTEGER :: i, j, k
41	REAL :: a, b, e_q, rifm, uv_total, z_p
42
43	!
44	!-- Compute theta*
45	IF ( constant_heatflux ) THEN
46	!
47	!-- For a given heat flux in the Prandtl layer:
48	!-- for u* use the value from the previous time step
49	!$OMP PARALLEL DO
50	DO i = nxl-1, nxr+1
51	DO j = nys-1, nyn+1
52	ts(j,i) = -shf(j,i) / ( us(j,i) + 1E-30 )
53	!
54	!-- ts must be limited, because otherwise overflow may occur in case of
55	!-- us=0 when computing rif further below
56	IF ( ts(j,i) < -1.05E5 ) ts = -1.0E5
57	IF ( ts(j,i) > 1.0E5 ) ts = 1.0E5
58	ENDDO
59	ENDDO
60
61	ELSE
62	!
63	!-- For a given surface temperature:
64	!-- (the Richardson number is still the one from the previous time step)
65	!$OMP PARALLEL DO PRIVATE( a, b, k, z_p )
66	DO i = nxl-1, nxr+1
67	DO j = nys-1, nyn+1
68
69	k = nzb_s_inner(j,i)
70	z_p = zu(k+1) - zw(k)
71
72	IF ( rif(j,i) >= 0.0 ) THEN
73	!
74	!-- Stable stratification
75	ts(j,i) = kappa * ( pt(k+1,j,i) - pt(k,j,i) ) / ( &
76	LOG( z_p / z0(j,i) ) + &
77	5.0 * rif(j,i) * ( z_p - z0(j,i) ) / z_p &
78	)
79	ELSE
80	!
81	!-- Unstable stratification
82	a = SQRT( 1.0 - 16.0 * rif(j,i) )
83	b = SQRT( 1.0 - 16.0 * rif(j,i) / z_p * z0(j,i) )
84	!
85	!-- If a borderline case occurs, the formula for stable
86	!-- stratification must be used anyway, or else a zero division
87	!-- would occur in the argument of the logarithm
88	IF ( a == 1.0 .OR. b == 1.0 ) THEN
89	ts(j,i) = kappa * ( pt(k+1,j,i) - pt(k,j,i) ) / ( &
90	LOG( z_p / z0(j,i) ) + &
91	5.0 * rif(j,i) * ( z_p - z0(j,i) ) / z_p &
92	)
93	ELSE
94	ts(j,i) = kappa * ( pt(k+1,j,i) - pt(k,j,i) ) / ( &
95	LOG( (1.0+b) / (1.0-b) * (1.0-a) / (1.0+a) ) &
96	)
97	ENDIF
98	ENDIF
99
100	ENDDO
101	ENDDO
102	ENDIF
103
104	!
105	!-- Compute z_p/L (corresponds to the Richardson-flux number)
106	IF ( .NOT. humidity ) THEN
107	!$OMP PARALLEL DO PRIVATE( k, z_p )
108	DO i = nxl-1, nxr+1
109	DO j = nys-1, nyn+1
110	k = nzb_s_inner(j,i)
111	z_p = zu(k+1) - zw(k)
112	rif(j,i) = z_p * kappa * g * ts(j,i) / &
113	( pt(k+1,j,i) * ( us(j,i)**2 + 1E-30 ) )
114	!
115	!-- Limit the value range of the Richardson numbers.
116	!-- This is necessary for very small velocities (u,v --> 0), because
117	!-- the absolute value of rif can then become very large, which in
118	!-- consequence would result in very large shear stresses and very
119	!-- small momentum fluxes (both are generally unrealistic).
120	IF ( rif(j,i) < rif_min ) rif(j,i) = rif_min
121	IF ( rif(j,i) > rif_max ) rif(j,i) = rif_max
122	ENDDO
123	ENDDO
124	ELSE
125	!$OMP PARALLEL DO PRIVATE( k, z_p )
126	DO i = nxl-1, nxr+1
127	DO j = nys-1, nyn+1
128	k = nzb_s_inner(j,i)
129	z_p = zu(k+1) - zw(k)
130	rif(j,i) = z_p * kappa * g * &
131	( ts(j,i) + 0.61 * pt(k+1,j,i) * qs(j,i) ) / &
132	( vpt(k+1,j,i) * ( us(j,i)**2 + 1E-30 ) )
133	!
134	!-- Limit the value range of the Richardson numbers.
135	!-- This is necessary for very small velocities (u,v --> 0), because
136	!-- the absolute value of rif can then become very large, which in
137	!-- consequence would result in very large shear stresses and very
138	!-- small momentum fluxes (both are generally unrealistic).
139	IF ( rif(j,i) < rif_min ) rif(j,i) = rif_min
140	IF ( rif(j,i) > rif_max ) rif(j,i) = rif_max
141	ENDDO
142	ENDDO
143	ENDIF
144
145	!
146	!-- Compute u* at the scalars' grid points
147	!$OMP PARALLEL DO PRIVATE( a, b, k, uv_total, z_p )
148	DO i = nxl, nxr
149	DO j = nys, nyn
150
151	k = nzb_s_inner(j,i)
152	z_p = zu(k+1) - zw(k)
153
154	!
155	!-- Compute the absolute value of the horizontal velocity
156	uv_total = SQRT( ( 0.5 * ( u(k+1,j,i) + u(k+1,j,i+1) ) )**2 + &
157	( 0.5 * ( v(k+1,j,i) + v(k+1,j+1,i) ) )**2 &
158	)
159
160	IF ( rif(j,i) >= 0.0 ) THEN
161	!
162	!-- Stable stratification
163	us(j,i) = kappa * uv_total / ( &
164	LOG( z_p / z0(j,i) ) + &
165	5.0 * rif(j,i) * ( z_p - z0(j,i) ) / z_p &
166	)
167	ELSE
168	!
169	!-- Unstable stratification
170	a = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rif(j,i) ) )
171	b = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rif(j,i) / z_p * z0(j,i) ) )
172	!
173	!-- If a borderline case occurs, the formula for stable stratification
174	!-- must be used anyway, or else a zero division would occur in the
175	!-- argument of the logarithm.
176	IF ( a == 1.0 .OR. b == 1.0 ) THEN
177	us(j,i) = kappa * uv_total / ( &
178	LOG( z_p / z0(j,i) ) + &
179	5.0 * rif(j,i) * ( z_p - z0(j,i) ) / z_p &
180	)
181	ELSE
182	us(j,i) = kappa * uv_total / ( &
183	LOG( (1.0+b) / (1.0-b) * (1.0-a) / (1.0+a) ) + &
184	2.0 * ( ATAN( b ) - ATAN( a ) ) &
185	)
186	ENDIF
187	ENDIF
188	ENDDO
189	ENDDO
190
191	!
192	!-- Compute u'w' for the total model domain.
193	!-- First compute the corresponding component of u* and square it.
194	!$OMP PARALLEL DO PRIVATE( a, b, k, rifm, z_p )
195	DO i = nxl, nxr
196	DO j = nys, nyn
197
198	k = nzb_u_inner(j,i)
199	z_p = zu(k+1) - zw(k)
200
201	!
202	!-- Compute Richardson-flux number for this point
203	rifm = 0.5 * ( rif(j,i-1) + rif(j,i) )
204	IF ( rifm >= 0.0 ) THEN
205	!
206	!-- Stable stratification
207	usws(j,i) = kappa * u(k+1,j,i) / ( &
208	LOG( z_p / z0(j,i) ) + &
209	5.0 * rifm * ( z_p - z0(j,i) ) / z_p &
210	)
211	ELSE
212	!
213	!-- Unstable stratification
214	a = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rifm ) )
215	b = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rifm / z_p * z0(j,i) ) )
216	!
217	!-- If a borderline case occurs, the formula for stable stratification
218	!-- must be used anyway, or else a zero division would occur in the
219	!-- argument of the logarithm.
220	IF ( a == 1.0 .OR. B == 1.0 ) THEN
221	usws(j,i) = kappa * u(k+1,j,i) / ( &
222	LOG( z_p / z0(j,i) ) + &
223	5.0 * rifm * ( z_p - z0(j,i) ) / z_p &
224	)
225	ELSE
226	usws(j,i) = kappa * u(k+1,j,i) / ( &
227	LOG( (1.0+b) / (1.0-b) * (1.0-a) / (1.0+a) ) + &
228	2.0 * ( ATAN( b ) - ATAN( a ) ) &
229	)
230	ENDIF
231	ENDIF
232	usws(j,i) = -usws(j,i) * ABS( usws(j,i) )
233	ENDDO
234	ENDDO
235
236	!
237	!-- Compute v'w' for the total model domain.
238	!-- First compute the corresponding component of u* and square it.
239	!$OMP PARALLEL DO PRIVATE( a, b, k, rifm, z_p )
240	DO i = nxl, nxr
241	DO j = nys, nyn
242
243	k = nzb_v_inner(j,i)
244	z_p = zu(k+1) - zw(k)
245
246	!
247	!-- Compute Richardson-flux number for this point
248	rifm = 0.5 * ( rif(j-1,i) + rif(j,i) )
249	IF ( rifm >= 0.0 ) THEN
250	!
251	!-- Stable stratification
252	vsws(j,i) = kappa * v(k+1,j,i) / ( &
253	LOG( z_p / z0(j,i) ) + &
254	5.0 * rifm * ( z_p - z0(j,i) ) / z_p &
255	)
256	ELSE
257	!
258	!-- Unstable stratification
259	a = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rifm ) )
260	b = 1.0 / SQRT( SQRT( 1.0 - 16.0 * rifm / z_p * z0(j,i) ) )
261	!
262	!-- If a borderline case occurs, the formula for stable stratification
263	!-- must be used anyway, or else a zero division would occur in the
264	!-- argument of the logarithm.
265	IF ( a == 1.0 .OR. b == 1.0 ) THEN
266	vsws(j,i) = kappa * v(k+1,j,i) / ( &
267	LOG( z_p / z0(j,i) ) + &
268	5.0 * rifm * ( z_p - z0(j,i) ) / z_p &
269	)
270	ELSE
271	vsws(j,i) = kappa * v(k+1,j,i) / ( &
272	LOG( (1.0+b) / (1.0-b) * (1.0-a) / (1.0+a) ) + &
273	2.0 * ( ATAN( b ) - ATAN( a ) ) &
274	)
275	ENDIF
276	ENDIF
277	vsws(j,i) = -vsws(j,i) * ABS( vsws(j,i) )
278	ENDDO
279	ENDDO
280
281	!
282	!-- If required compute q*
283	IF ( humidity .OR. passive_scalar ) THEN
284	IF ( constant_waterflux ) THEN
285	!
286	!-- For a given water flux in the Prandtl layer:
287	!$OMP PARALLEL DO
288	DO i = nxl-1, nxr+1
289	DO j = nys-1, nyn+1
290	qs(j,i) = -qsws(j,i) / ( us(j,i) + 1E-30 )
291	ENDDO
292	ENDDO
293
294	ELSE
295	!$OMP PARALLEL DO PRIVATE( a, b, k, z_p )
296	DO i = nxl-1, nxr+1
297	DO j = nys-1, nyn+1
298
299	k = nzb_s_inner(j,i)
300	z_p = zu(k+1) - zw(k)
301
302	!
303	!-- assume saturation for atmosphere coupled to ocean
304	IF ( coupling_mode == 'atmosphere_to_ocean' ) THEN
305	e_q = 6.1 * &
306	EXP( 0.07 * ( MIN(pt(0,j,i),pt(1,j,i)) - 273.15 ) )
307	q(k,j,i) = 0.622 * e_q / ( surface_pressure - e_q )
308	ENDIF
309	IF ( rif(j,i) >= 0.0 ) THEN
310	!
311	!-- Stable stratification
312	qs(j,i) = kappa * ( q(k+1,j,i) - q(k,j,i) ) / ( &
313	LOG( z_p / z0(j,i) ) + &
314	5.0 * rif(j,i) * ( z_p - z0(j,i) ) / z_p &
315	)
316	ELSE
317	!
318	!-- Unstable stratification
319	a = SQRT( 1.0 - 16.0 * rif(j,i) )
320	b = SQRT( 1.0 - 16.0 * rif(j,i) / z_p * z0(j,i) )
321	!
322	!-- If a borderline case occurs, the formula for stable
323	!-- stratification must be used anyway, or else a zero division
324	!-- would occur in the argument of the logarithm.
325	IF ( a == 1.0 .OR. b == 1.0 ) THEN
326	qs(j,i) = kappa * ( q(k+1,j,i) - q(k,j,i) ) / ( &
327	LOG( z_p / z0(j,i) ) + &
328	5.0 * rif(j,i) * ( z_p - z0(j,i) ) / z_p &
329	)
330	ELSE
331	qs(j,i) = kappa * ( q(k+1,j,i) - q(k,j,i) ) / ( &
332	LOG( (1.0+b) / (1.0-b) * (1.0-a) / (1.0+a) ) &
333	)
334	ENDIF
335	ENDIF
336
337	ENDDO
338	ENDDO
339	ENDIF
340	ENDIF
341
342	!
343	!-- Exchange the boundaries for u* and the momentum fluxes (fluxes only for
344	!-- completeness's sake).
345	CALL exchange_horiz_2d( us )
346	CALL exchange_horiz_2d( usws )
347	CALL exchange_horiz_2d( vsws )
348	IF ( humidity .OR. passive_scalar ) CALL exchange_horiz_2d( qsws )
349
350	!
351	!-- Compute the vertical kinematic heat flux
352	IF ( .NOT. constant_heatflux ) THEN
353	!$OMP PARALLEL DO
354	DO i = nxl-1, nxr+1
355	DO j = nys-1, nyn+1
356	shf(j,i) = -ts(j,i) * us(j,i)
357	ENDDO
358	ENDDO
359	ENDIF
360
361	!
362	!-- Compute the vertical water/scalar flux
363	IF ( .NOT. constant_heatflux .AND. ( humidity .OR. passive_scalar ) ) THEN
364	!$OMP PARALLEL DO
365	DO i = nxl-1, nxr+1
366	DO j = nys-1, nyn+1
367	qsws(j,i) = -qs(j,i) * us(j,i)
368	ENDDO
369	ENDDO
370	ENDIF
371
372	!
373	!-- Bottom boundary condition for the TKE
374	IF ( ibc_e_b == 2 ) THEN
375	!$OMP PARALLEL DO
376	DO i = nxl-1, nxr+1
377	DO j = nys-1, nyn+1
378	e(nzb_s_inner(j,i)+1,j,i) = ( us(j,i) / 0.1 )**2
379	!
380	!-- As a test: cm = 0.4
381	! e(nzb_s_inner(j,i)+1,j,i) = ( us(j,i) / 0.4 )**2
382	e(nzb_s_inner(j,i),j,i) = e(nzb_s_inner(j,i)+1,j,i)
383	ENDDO
384	ENDDO
385	ENDIF
386
387
388	END SUBROUTINE prandtl_fluxes

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