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source: palm/trunk/SOURCE/lpm_splitting.f90 @ 3499

Last change on this file since 3499 was 3274, checked in by knoop, 6 years ago
Modularization of all bulk cloud physics code components
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[2263]	1	!> @file lpm_splitting.f90
	2	!------------------------------------------------------------------------------!
[2696]	3	! This file is part of the PALM model system.
[2263]	4	!
	5	! PALM is free software: you can redistribute it and/or modify it under the
	6	! terms of the GNU General Public License as published by the Free Software
	7	! Foundation, either version 3 of the License, or (at your option) any later
	8	! version.
	9	!
	10	! PALM is distributed in the hope that it will be useful, but WITHOUT ANY
	11	! WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
	12	! A PARTICULAR PURPOSE. See the GNU General Public License for more details.
	13	!
	14	! You should have received a copy of the GNU General Public License along with
	15	! PALM. If not, see <http://www.gnu.org/licenses/>.
	16	!
[2718]	17	! Copyright 1997-2018 Leibniz Universitaet Hannover
[2263]	18	!------------------------------------------------------------------------------!
	19	!
	20	! Current revisions:
	21	! ------------------
[2270]	22	!
	23	!
[2263]	24	! Former revisions:
	25	! -----------------
[2716]	26	! $Id: lpm_splitting.f90 3274 2018-09-24 15:42:55Z suehring $
[3274]	27	! Modularization of all bulk cloud physics code components
	28	!
	29	! 3241 2018-09-12 15:02:00Z raasch
	30	! unused variables removed
	31	!
	32	! 2932 2018-03-26 09:39:22Z maronga
[2932]	33	! renamed particles_par to particle_parameters
	34	!
[3274]	35	! 2718 2018-01-02 08:49:38Z maronga
[2716]	36	! Corrected "Former revisions" section
[2696]	37	!
[2932]	38	!
[2716]	39	! Change in file header (GPL part)
	40	!
[2278]	41	! Added comments
[2270]	42	!
[2696]	43	!
[2278]	44	! 2263 2017-06-08 14:59:01Z schwenkel
[2263]	45	! Initial revision
	46	!
	47	!
	48	!
	49	! Description:
	50	! ------------
	51	! This routine is a part of the Lagrangian particle model. Super droplets which
	52	! fulfill certain criterion's (e.g. a big weighting factor and a large radius)
	53	! can be split into several super droplets with a reduced number of
	54	! represented particles of every super droplet. This mechanism ensures an
	55	! improved representation of the right tail of the drop size distribution with
	56	! a feasible amount of computational costs. The limits of particle creation
	57	! should be chosen carefully! The idea of this algorithm is based on
	58	! Unterstrasser and Soelch, 2014.
	59	!------------------------------------------------------------------------------!
	60	SUBROUTINE lpm_splitting
	61
	62
	63	USE arrays_3d, &
	64	ONLY: ql
	65
[3274]	66	USE basic_constants_and_equations_mod, &
	67	ONLY: pi, rho_l
[2263]	68
	69	USE cpulog, &
	70	ONLY: cpu_log, log_point_s
	71
	72	USE indices, &
	73	ONLY: nxl, nxr, nyn, nys, nzb, nzt
	74
	75	USE kinds
	76
	77	USE lpm_exchange_horiz_mod, &
	78	ONLY: realloc_particles_array
	79
	80	USE particle_attributes, &
[3241]	81	ONLY: grid_particles, initial_weighting_factor, isf, i_splitting_mode,&
	82	max_number_particles_per_gridbox, new_particles, n_max, &
	83	number_of_particles, particles, particle_type, prt_count, &
	84	radius_split, splitting_factor, splitting_factor_max, &
[2263]	85	sum_new_particles, weight_factor_split
	86
	87	USE pegrid
	88
	89	IMPLICIT NONE
	90
	91	INTEGER(iwp) :: i !<
	92	INTEGER(iwp) :: j !<
	93	INTEGER(iwp) :: jpp !<
	94	INTEGER(iwp) :: k !<
	95	INTEGER(iwp) :: n !<
	96	INTEGER(iwp) :: new_particles_gb !< counter of created particles within one grid box
	97	INTEGER(iwp) :: new_size !< new particle array size
[2278]	98	INTEGER(iwp) :: np !<
[2263]	99	INTEGER(iwp) :: old_size !< old particle array size
	100
	101	LOGICAL :: first_loop_stride = .TRUE. !< flag to calculate constants only once
	102
	103	REAL(wp) :: diameter !< diameter of droplet
	104	REAL(wp) :: dlog !< factor for DSD calculation
	105	REAL(wp) :: factor_volume_to_mass !< pre calculate factor volume to mass
	106	REAL(wp) :: lambda !< slope parameter of gamma-distribution
	107	REAL(wp) :: lwc !< liquid water content of grid box
	108	REAL(wp) :: lwc_total !< average liquid water content of cloud
	109	REAL(wp) :: m1 !< first moment of DSD
	110	REAL(wp) :: m1_total !< average over all PEs of first moment of DSD
	111	REAL(wp) :: m2 !< second moment of DSD
	112	REAL(wp) :: m2_total !< average average over all PEs second moment of DSD
	113	REAL(wp) :: m3 !< third moment of DSD
	114	REAL(wp) :: m3_total !< average average over all PEs third moment of DSD
	115	REAL(wp) :: mu !< spectral shape parameter of gamma distribution
	116	REAL(wp) :: nrclgb !< number of cloudy grid boxes (ql >= 1.0E-5 kg/kg)
	117	REAL(wp) :: nrclgb_total !< average over all PEs of number of cloudy grid boxes
	118	REAL(wp) :: nr !< number concentration of cloud droplets
	119	REAL(wp) :: nr_total !< average over all PEs of number of cloudy grid boxes
	120	REAL(wp) :: nr0 !< intercept parameter of gamma distribution
	121	REAL(wp) :: pirho_l !< pi * rho_l / 6.0
	122	REAL(wp) :: ql_crit = 1.0E-5_wp !< threshold lwc for cloudy grid cells
	123	!< (Siebesma et al 2003, JAS, 60)
	124	REAL(wp) :: rm !< volume averaged mean radius
	125	REAL(wp) :: rm_total !< average over all PEs of volume averaged mean radius
	126	REAL(wp) :: r_min = 1.0E-6_wp !< minimum radius of approximated spectra
	127	REAL(wp) :: r_max = 1.0E-3_wp !< maximum radius of approximated spectra
	128	REAL(wp) :: sigma_log = 1.5_wp !< standard deviation of the LOG-distribution
	129	REAL(wp) :: zeta !< Parameter for DSD calculation of Seifert
	130
	131	REAL(wp), DIMENSION(0:n_max-1) :: an_spl !< size dependent critical weight factor
	132	REAL(wp), DIMENSION(0:n_max-1) :: r_bin_mid !< mass weighted mean radius of a bin
	133	REAL(wp), DIMENSION(0:n_max) :: r_bin !< boundaries of a radius bin
	134
	135	TYPE(particle_type) :: tmp_particle !< temporary particle TYPE
	136
	137	CALL cpu_log( log_point_s(80), 'lpm_splitting', 'start' )
	138
	139	IF ( first_loop_stride ) THEN
	140	IF ( i_splitting_mode == 2 .OR. i_splitting_mode == 3 ) THEN
	141	dlog = ( LOG10(r_max) - LOG10(r_min) ) / ( n_max - 1 )
	142	DO i = 0, n_max-1
	143	r_bin(i) = 10.0_wp*( LOG10(r_min) + i dlog - 0.5_wp * dlog )
	144	r_bin_mid(i) = 10.0_wp*( LOG10(r_min) + i dlog )
	145	ENDDO
	146	r_bin(n_max) = 10.0_wp*( LOG10(r_min) + n_max dlog - 0.5_wp * dlog )
	147	ENDIF
	148	factor_volume_to_mass = 4.0_wp / 3.0_wp * pi * rho_l
	149	pirho_l = pi * rho_l / 6.0_wp
	150	IF ( weight_factor_split == -1.0_wp ) THEN
	151	weight_factor_split = 0.1_wp * initial_weighting_factor
	152	ENDIF
	153	ENDIF
	154
	155	new_particles = 0
	156
	157	IF ( i_splitting_mode == 1 ) THEN
	158
	159	DO i = nxl, nxr
	160	DO j = nys, nyn
	161	DO k = nzb+1, nzt
	162
	163	new_particles_gb = 0
	164	number_of_particles = prt_count(k,j,i)
	165	IF ( number_of_particles <= 0 .OR. &
	166	ql(k,j,i) < ql_crit ) CYCLE
	167	particles => grid_particles(k,j,i)%particles(1:number_of_particles)
	168	!
	169	!-- Start splitting operations. Each particle is checked if it
	170	!-- fulfilled the splitting criterion's. In splitting mode 'const'
	171	!-- a critical radius (radius_split) a critical weighting factor
	172	!-- (weight_factor_split) and a splitting factor (splitting_factor)
[2932]	173	!-- must be prescribed (see particle_parameters). Super droplets
	174	!-- which have a larger radius and larger weighting factor are split
	175	!-- into 'splitting_factor' super droplets. Therefore, the weighting
[2263]	176	!-- factor of the super droplet and all created clones is reduced
	177	!-- by the factor of 'splitting_factor'.
	178	DO n = 1, number_of_particles
	179	IF ( particles(n)%particle_mask .AND. &
	180	particles(n)%radius >= radius_split .AND. &
	181	particles(n)%weight_factor >= weight_factor_split ) &
	182	THEN
	183	!
	184	!-- Calculate the new number of particles.
	185	new_size = prt_count(k,j,i) + splitting_factor - 1
	186	!
	187	!-- Cycle if maximum number of particles per grid box
	188	!-- is greater than the allowed maximum number.
	189	IF ( new_size >= max_number_particles_per_gridbox ) CYCLE
	190	!
	191	!-- Reallocate particle array if necessary.
	192	IF ( new_size > SIZE(particles) ) THEN
	193	CALL realloc_particles_array(i,j,k,new_size)
	194	ENDIF
	195	old_size = prt_count(k,j,i)
	196	!
	197	!-- Calculate new weighting factor.
	198	particles(n)%weight_factor = &
	199	particles(n)%weight_factor / splitting_factor
	200	tmp_particle = particles(n)
	201	!
	202	!-- Create splitting_factor-1 new particles.
	203	DO jpp = 1, splitting_factor-1
	204	grid_particles(k,j,i)%particles(jpp+old_size) = &
	205	tmp_particle
	206	ENDDO
	207	new_particles_gb = new_particles_gb + splitting_factor - 1
	208	!
	209	!-- Save the new number of super droplets for every grid box.
	210	prt_count(k,j,i) = prt_count(k,j,i) + &
	211	splitting_factor - 1
	212	ENDIF
	213	ENDDO
	214
	215	new_particles = new_particles + new_particles_gb
	216	sum_new_particles = sum_new_particles + new_particles_gb
	217	ENDDO
	218	ENDDO
	219	ENDDO
	220
	221	ELSEIF ( i_splitting_mode == 2 ) THEN
	222	!
	223	!-- Initialize summing variables.
	224	lwc = 0.0_wp
	225	lwc_total = 0.0_wp
	226	m1 = 0.0_wp
	227	m1_total = 0.0_wp
	228	m2 = 0.0_wp
	229	m2_total = 0.0_wp
	230	m3 = 0.0_wp
	231	m3_total = 0.0_wp
	232	nr = 0.0_wp
	233	nrclgb = 0.0_wp
	234	nrclgb_total = 0.0_wp
	235	nr_total = 0.0_wp
	236	rm = 0.0_wp
	237	rm_total = 0.0_wp
	238
	239	DO i = nxl, nxr
	240	DO j = nys, nyn
	241	DO k = nzb+1, nzt
	242	number_of_particles = prt_count(k,j,i)
	243	IF ( number_of_particles <= 0 .OR. &
	244	ql(k,j,i) < ql_crit ) CYCLE
	245	particles => grid_particles(k,j,i)%particles(1:number_of_particles)
	246	nrclgb = nrclgb + 1.0_wp
	247	!
	248	!-- Calculate moments of DSD.
	249	DO n = 1, number_of_particles
	250	IF ( particles(n)%particle_mask .AND. &
	251	particles(n)%radius >= r_min ) &
	252	THEN
	253	nr = nr + particles(n)%weight_factor
	254	rm = rm + factor_volume_to_mass * &
	255	particles(n)%radius*3 &
	256	particles(n)%weight_factor
	257	IF ( isf == 1 ) THEN
	258	diameter = particles(n)%radius * 2.0_wp
	259	lwc = lwc + factor_volume_to_mass * &
	260	particles(n)%radius*3 &
	261	particles(n)%weight_factor
	262	m1 = m1 + particles(n)%weight_factor * diameter
	263	m2 = m2 + particles(n)%weight_factor * diameter**2
	264	m3 = m3 + particles(n)%weight_factor * diameter**3
	265	ENDIF
	266	ENDIF
	267	ENDDO
	268	ENDDO
	269	ENDDO
	270	ENDDO
	271
	272	#if defined( __parallel )
	273	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
	274	CALL MPI_ALLREDUCE( nr, nr_total, 1 , &
	275	MPI_REAL, MPI_SUM, comm2d, ierr )
	276	CALL MPI_ALLREDUCE( rm, rm_total, 1 , &
	277	MPI_REAL, MPI_SUM, comm2d, ierr )
	278	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
	279	CALL MPI_ALLREDUCE( nrclgb, nrclgb_total, 1 , &
	280	MPI_REAL, MPI_SUM, comm2d, ierr )
	281	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
	282	CALL MPI_ALLREDUCE( lwc, lwc_total, 1 , &
	283	MPI_REAL, MPI_SUM, comm2d, ierr )
	284	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
	285	CALL MPI_ALLREDUCE( m1, m1_total, 1 , &
	286	MPI_REAL, MPI_SUM, comm2d, ierr )
	287	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
	288	CALL MPI_ALLREDUCE( m2, m2_total, 1 , &
	289	MPI_REAL, MPI_SUM, comm2d, ierr )
	290	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
	291	CALL MPI_ALLREDUCE( m3, m3_total, 1 , &
	292	MPI_REAL, MPI_SUM, comm2d, ierr )
	293	#endif
	294
	295	!
	296	!-- Calculate number concentration and mean volume averaged radius.
	297	nr_total = MERGE( nr_total / nrclgb_total, &
	298	0.0_wp, nrclgb_total > 0.0_wp &
	299	)
	300	rm_total = MERGE( ( rm_total / &
	301	( nr_total * factor_volume_to_mass ) &
	302	)**0.3333333_wp, 0.0_wp, nrclgb_total > 0.0_wp &
	303	)
	304	!
	305	!-- Check which function should be used to approximate the DSD.
	306	IF ( isf == 1 ) THEN
	307	lwc_total = MERGE( lwc_total / nrclgb_total, &
	308	0.0_wp, nrclgb_total > 0.0_wp &
	309	)
	310	m1_total = MERGE( m1_total / nrclgb_total, &
	311	0.0_wp, nrclgb_total > 0.0_wp &
	312	)
	313	m2_total = MERGE( m2_total / nrclgb_total, &
	314	0.0_wp, nrclgb_total > 0.0_wp &
	315	)
	316	m3_total = MERGE( m3_total / nrclgb_total, &
	317	0.0_wp, nrclgb_total > 0.0_wp &
	318	)
	319	zeta = m1_total * m3_total / m2_total**2
	320	mu = MAX( ( ( 1.0_wp - zeta ) * 2.0_wp + 1.0_wp ) / &
	321	( zeta - 1.0_wp ), 0.0_wp &
	322	)
	323
	324	lambda = ( pirho_l * nr_total / lwc_total * &
	325	( mu + 3.0_wp ) * ( mu + 2.0_wp ) * ( mu + 1.0_wp ) &
	326	)**0.3333333_wp
	327	nr0 = nr_total / gamma( mu + 1.0_wp ) * lambda**( mu + 1.0_wp )
	328
	329	DO n = 0, n_max-1
	330	diameter = r_bin_mid(n) * 2.0_wp
	331	an_spl(n) = nr0 * diameter*mu EXP( -lambda * diameter ) * &
	332	( r_bin(n+1) - r_bin(n) ) * 2.0_wp
	333	ENDDO
	334	ELSEIF ( isf == 2 ) THEN
	335	DO n = 0, n_max-1
	336	an_spl(n) = nr_total / ( SQRT( 2.0_wp * pi ) * &
	337	LOG(sigma_log) * r_bin_mid(n) &
	338	) * &
	339	EXP( -( LOG( r_bin_mid(n) / rm_total )**2 ) / &
	340	( 2.0_wp * LOG(sigma_log)**2 ) &
	341	) * &
	342	( r_bin(n+1) - r_bin(n) )
	343	ENDDO
	344	ELSEIF( isf == 3 ) THEN
	345	DO n = 0, n_max-1
	346	an_spl(n) = 3.0_wp * nr_total * r_bin_mid(n)2 / rm_total3 * &
	347	EXP( - ( r_bin_mid(n)3 / rm_total3 ) ) * &
	348	( r_bin(n+1) - r_bin(n) )
	349	ENDDO
	350	ENDIF
	351	!
	352	!-- Criterion to avoid super droplets with a weighting factor < 1.0.
	353	an_spl = MAX(an_spl, 1.0_wp)
	354
	355	DO i = nxl, nxr
	356	DO j = nys, nyn
	357	DO k = nzb+1, nzt
	358	number_of_particles = prt_count(k,j,i)
	359	IF ( number_of_particles <= 0 .OR. &
	360	ql(k,j,i) < ql_crit ) CYCLE
	361	particles => grid_particles(k,j,i)%particles(1:number_of_particles)
	362	new_particles_gb = 0
	363	!
	364	!-- Start splitting operations. Each particle is checked if it
	365	!-- fulfilled the splitting criterion's. In splitting mode 'cl_av'
	366	!-- a critical radius (radius_split) and a splitting function must
	367	!-- be prescribed (see particles_par). The critical weighting factor
	368	!-- is calculated while approximating a 'gamma', 'log' or 'exp'-
	369	!-- drop size distribution. In this mode the DSD is calculated as
	370	!-- an average over all cloudy grid boxes. Super droplets which
	371	!-- have a larger radius and larger weighting factor are split into
	372	!-- 'splitting_factor' super droplets. In this case the splitting
	373	!-- factor is calculated of weighting factor of the super droplet
	374	!-- and the approximated number concentration for droplet of such
	375	!-- a size. Due to the splitting, the weighting factor of the
	376	!-- super droplet and all created clones is reduced by the factor
	377	!-- of 'splitting_facor'.
	378	DO n = 1, number_of_particles
	379	DO np = 0, n_max-1
	380	IF ( r_bin(np) >= radius_split .AND. &
	381	particles(n)%particle_mask .AND. &
	382	particles(n)%radius >= r_bin(np) .AND. &
	383	particles(n)%radius < r_bin(np+1) .AND. &
	384	particles(n)%weight_factor >= an_spl(np) ) &
	385	THEN
	386	!
	387	!-- Calculate splitting factor
	388	splitting_factor = &
	389	MIN( INT( particles(n)%weight_factor / &
	390	an_spl(np) &
	391	), splitting_factor_max &
	392	)
	393	IF ( splitting_factor < 2 ) CYCLE
	394	!
	395	!-- Calculate the new number of particles.
	396	new_size = prt_count(k,j,i) + splitting_factor - 1
	397	!
	398	!-- Cycle if maximum number of particles per grid box
	399	!-- is greater than the allowed maximum number.
	400	IF ( new_size >= max_number_particles_per_gridbox ) &
	401	CYCLE
	402	!
	403	!-- Reallocate particle array if necessary.
	404	IF ( new_size > SIZE(particles) ) THEN
	405	CALL realloc_particles_array(i,j,k,new_size)
	406	ENDIF
	407	old_size = prt_count(k,j,i)
	408	new_particles_gb = new_particles_gb + &
	409	splitting_factor - 1
	410	!
	411	!-- Calculate new weighting factor.
	412	particles(n)%weight_factor = &
	413	particles(n)%weight_factor / splitting_factor
	414	tmp_particle = particles(n)
	415	!
	416	!-- Create splitting_factor-1 new particles.
	417	DO jpp = 1, splitting_factor-1
	418	grid_particles(k,j,i)%particles(jpp+old_size) = &
	419	tmp_particle
	420	ENDDO
	421	!
	422	!-- Save the new number of super droplets.
	423	prt_count(k,j,i) = prt_count(k,j,i) + &
	424	splitting_factor - 1
	425	ENDIF
	426	ENDDO
	427	ENDDO
	428
	429	new_particles = new_particles + new_particles_gb
	430	sum_new_particles = sum_new_particles + new_particles_gb
	431	ENDDO
	432	ENDDO
	433	ENDDO
	434
	435	ELSEIF ( i_splitting_mode == 3 ) THEN
	436
	437	DO i = nxl, nxr
	438	DO j = nys, nyn
	439	DO k = nzb+1, nzt
	440
	441	!
	442	!-- Initialize summing variables.
	443	lwc = 0.0_wp
	444	m1 = 0.0_wp
	445	m2 = 0.0_wp
	446	m3 = 0.0_wp
	447	nr = 0.0_wp
	448	rm = 0.0_wp
	449
	450	new_particles_gb = 0
	451	number_of_particles = prt_count(k,j,i)
	452	IF ( number_of_particles <= 0 .OR. &
	453	ql(k,j,i) < ql_crit ) CYCLE
	454	particles => grid_particles(k,j,i)%particles
	455	!
	456	!-- Calculate moments of DSD.
	457	DO n = 1, number_of_particles
	458	IF ( particles(n)%particle_mask .AND. &
	459	particles(n)%radius >= r_min ) &
	460	THEN
	461	nr = nr + particles(n)%weight_factor
	462	rm = rm + factor_volume_to_mass * &
	463	particles(n)%radius*3 &
	464	particles(n)%weight_factor
	465	IF ( isf == 1 ) THEN
	466	diameter = particles(n)%radius * 2.0_wp
	467	lwc = lwc + factor_volume_to_mass * &
	468	particles(n)%radius*3 &
	469	particles(n)%weight_factor
	470	m1 = m1 + particles(n)%weight_factor * diameter
	471	m2 = m2 + particles(n)%weight_factor * diameter**2
	472	m3 = m3 + particles(n)%weight_factor * diameter**3
	473	ENDIF
	474	ENDIF
	475	ENDDO
	476
	477	IF ( nr <= 0.0 .OR. rm <= 0.0_wp ) CYCLE
	478	!
	479	!-- Calculate mean volume averaged radius.
	480	rm = ( rm / ( nr * factor_volume_to_mass ) )**0.3333333_wp
	481	!
	482	!-- Check which function should be used to approximate the DSD.
	483	IF ( isf == 1 ) THEN
	484	!
	485	!-- Gamma size distribution to calculate
	486	!-- critical weight_factor (e.g. Marshall + Palmer, 1948).
	487	zeta = m1 * m3 / m2**2
	488	mu = MAX( ( ( 1.0_wp - zeta ) * 2.0_wp + 1.0_wp ) / &
	489	( zeta - 1.0_wp ), 0.0_wp &
	490	)
	491	lambda = ( pirho_l * nr / lwc * &
	492	( mu + 3.0_wp ) * ( mu + 2.0_wp ) * &
	493	( mu + 1.0_wp ) &
	494	)**0.3333333_wp
	495	nr0 = ( nr / (gamma( mu + 1.0_wp ) ) ) * &
	496	lambda**( mu + 1.0_wp )
	497
	498	DO n = 0, n_max-1
	499	diameter = r_bin_mid(n) * 2.0_wp
	500	an_spl(n) = nr0 * diameter*mu &
	501	EXP( -lambda * diameter ) * &
	502	( r_bin(n+1) - r_bin(n) ) * 2.0_wp
	503	ENDDO
	504	ELSEIF ( isf == 2 ) THEN
	505	!
	506	!-- Lognormal size distribution to calculate critical
	507	!-- weight_factor (e.g. Levin, 1971, Bradley + Stow, 1974).
	508	DO n = 0, n_max-1
	509	an_spl(n) = nr / ( SQRT( 2.0_wp * pi ) * &
	510	LOG(sigma_log) * r_bin_mid(n) &
	511	) * &
	512	EXP( -( LOG( r_bin_mid(n) / rm )**2 ) / &
	513	( 2.0_wp * LOG(sigma_log)**2 ) &
	514	) * &
	515	( r_bin(n+1) - r_bin(n) )
	516	ENDDO
	517	ELSEIF ( isf == 3 ) THEN
	518	!
	519	!-- Exponential size distribution to calculate critical
	520	!-- weight_factor (e.g. Berry + Reinhardt, 1974).
	521	DO n = 0, n_max-1
	522	an_spl(n) = 3.0_wp * nr * r_bin_mid(n)2 / rm3 * &
	523	EXP( - ( r_bin_mid(n)3 / rm3 ) ) * &
	524	( r_bin(n+1) - r_bin(n) )
	525	ENDDO
	526	ENDIF
	527
	528	!
	529	!-- Criterion to avoid super droplets with a weighting factor < 1.0.
	530	an_spl = MAX(an_spl, 1.0_wp)
	531	!
	532	!-- Start splitting operations. Each particle is checked if it
	533	!-- fulfilled the splitting criterion's. In splitting mode 'gb_av'
	534	!-- a critical radius (radius_split) and a splitting function must
	535	!-- be prescribed (see particles_par). The critical weighting factor
	536	!-- is calculated while appoximating a 'gamma', 'log' or 'exp'-
	537	!-- drop size distribution. In this mode a DSD is calculated for
	538	!-- every cloudy grid box. Super droplets which have a larger
	539	!-- radius and larger weighting factor are split into
	540	!-- 'splitting_factor' super droplets. In this case the splitting
	541	!-- factor is calculated of weighting factor of the super droplet
	542	!-- and theapproximated number concentration for droplet of such
	543	!-- a size. Due to the splitting, the weighting factor of the
	544	!-- super droplet and all created clones is reduced by the factor
	545	!-- of 'splitting_facor'.
	546	DO n = 1, number_of_particles
	547	DO np = 0, n_max-1
	548	IF ( r_bin(np) >= radius_split .AND. &
	549	particles(n)%particle_mask .AND. &
	550	particles(n)%radius >= r_bin(np) .AND. &
	551	particles(n)%radius < r_bin(np+1) .AND. &
	552	particles(n)%weight_factor >= an_spl(np) ) &
	553	THEN
	554	!
	555	!-- Calculate splitting factor.
	556	splitting_factor = &
	557	MIN( INT( particles(n)%weight_factor / &
	558	an_spl(np) &
	559	), splitting_factor_max &
	560	)
	561	IF ( splitting_factor < 2 ) CYCLE
	562
	563	!
	564	!-- Calculate the new number of particles.
	565	new_size = prt_count(k,j,i) + splitting_factor - 1
	566	!
	567	!-- Cycle if maximum number of particles per grid box
	568	!-- is greater than the allowed maximum number.
	569	IF ( new_size >= max_number_particles_per_gridbox ) &
	570	CYCLE
	571	!
	572	!-- Reallocate particle array if necessary.
	573	IF ( new_size > SIZE(particles) ) THEN
	574	CALL realloc_particles_array(i,j,k,new_size)
	575	ENDIF
	576	!
	577	!-- Calculate new weighting factor.
	578	particles(n)%weight_factor = &
	579	particles(n)%weight_factor / splitting_factor
	580	tmp_particle = particles(n)
	581	old_size = prt_count(k,j,i)
	582	!
	583	!-- Create splitting_factor-1 new particles.
	584	DO jpp = 1, splitting_factor-1
	585	grid_particles(k,j,i)%particles(jpp+old_size) = &
	586	tmp_particle
	587	ENDDO
	588	!
	589	!-- Save the new number of droplets for every grid box.
	590	prt_count(k,j,i) = prt_count(k,j,i) + &
	591	splitting_factor - 1
	592	new_particles_gb = new_particles_gb + &
	593	splitting_factor - 1
	594	ENDIF
	595	ENDDO
	596	ENDDO
	597
	598	new_particles = new_particles + new_particles_gb
	599	sum_new_particles = sum_new_particles + new_particles_gb
	600	ENDDO
	601	ENDDO
	602	ENDDO
	603	ENDIF
	604
	605	CALL cpu_log( log_point_s(80), 'lpm_splitting', 'stop' )
	606
	607	END SUBROUTINE lpm_splitting
	608

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