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source: palm/trunk/SOURCE/lpm_collision_kernels.f90 @ 883

Last change on this file since 883 was 850, checked in by raasch, 13 years ago
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[828]	1	MODULE lpm_collision_kernels_mod
[790]	2
	3	!------------------------------------------------------------------------------!
	4	! Current revisions:
	5	! -----------------
[850]	6	!
[829]	7	!
	8	! Former revisions:
	9	! -----------------
	10	! $Id: lpm_collision_kernels.f90 850 2012-03-15 12:09:25Z suehring $
	11	!
[850]	12	! 849 2012-03-15 10:35:09Z raasch
	13	! routine collision_efficiency_rogers added (moved from former advec_particles
	14	! to here)
	15	!
[836]	16	! 835 2012-02-22 11:21:19Z raasch $
	17	! Bugfix: array diss can be used only in case of Wang kernel
	18	!
[829]	19	! 828 2012-02-21 12:00:36Z raasch
[828]	20	! code has been completely reformatted, routine colker renamed
	21	! recalculate_kernel,
	22	! routine init_kernels added, radius is now communicated to the collision
	23	! routines by array radclass
[790]	24	!
[828]	25	! Bugfix: transformation factor for dissipation changed from 1E5 to 1E4
	26	!
[826]	27	! 825 2012-02-19 03:03:44Z raasch
	28	! routine renamed from wang_kernel to lpm_collision_kernels,
	29	! turbulence_effects on collision replaced by wang_kernel
	30	!
[800]	31	! 799 2011-12-21 17:48:03Z franke
	32	! speed optimizations and formatting
	33	! Bugfix: iq=1 is not allowed (routine effic)
	34	! Bugfix: replaced stop by ec=0.0 in case of very small ec (routine effic)
	35	!
[791]	36	! 790 2011-11-29 03:11:20Z raasch
	37	! initial revision
[790]	38	!
	39	! Description:
	40	! ------------
[828]	41	! This module calculates collision efficiencies either due to pure gravitational
	42	! effects (Hall kernel, see Hall, 1980: J. Atmos. Sci., 2486-2507) or
	43	! including the effects of (SGS) turbulence (Wang kernel, see Wang and
	44	! Grabowski, 2009: Atmos. Sci. Lett., 10, 1-8). The original code has been
	45	! provided by L.-P. Wang but is substantially reformatted and speed optimized
	46	! here.
	47	!
	48	! ATTENTION:
	49	! Physical quantities (like g, densities, etc.) used in this module still
	50	! have to be adjusted to those values used in the main PALM code.
	51	! Also, quantities in CGS-units should be converted to SI-units eventually.
[790]	52	!------------------------------------------------------------------------------!
	53
	54	USE arrays_3d
	55	USE cloud_parameters
	56	USE constants
	57	USE particle_attributes
[828]	58	USE pegrid
[790]	59
[828]	60
[790]	61	IMPLICIT NONE
	62
	63	PRIVATE
	64
[849]	65	PUBLIC ckernel, collision_efficiency_rogers, init_kernels, &
	66	rclass_lbound, rclass_ubound, recalculate_kernel
[790]	67
[828]	68	REAL :: epsilon, eps2, rclass_lbound, rclass_ubound, urms, urms2
[790]	69
[828]	70	REAL, DIMENSION(:), ALLOCATABLE :: epsclass, radclass, winf
	71	REAL, DIMENSION(:,:), ALLOCATABLE :: ec, ecf, gck, hkernel, hwratio
	72	REAL, DIMENSION(:,:,:), ALLOCATABLE :: ckernel
[792]	73
[828]	74	SAVE
[792]	75
[790]	76	!
	77	!-- Public interfaces
[849]	78	INTERFACE collision_efficiency_rogers
	79	MODULE PROCEDURE collision_efficiency_rogers
	80	END INTERFACE collision_efficiency_rogers
	81
[828]	82	INTERFACE init_kernels
	83	MODULE PROCEDURE init_kernels
	84	END INTERFACE init_kernels
[790]	85
[828]	86	INTERFACE recalculate_kernel
	87	MODULE PROCEDURE recalculate_kernel
	88	END INTERFACE recalculate_kernel
[790]	89
	90
[828]	91	CONTAINS
[790]	92
[792]	93
[828]	94	SUBROUTINE init_kernels
	95	!------------------------------------------------------------------------------!
	96	! Initialization of the collision efficiency matrix with fixed radius and
	97	! dissipation classes, calculated at simulation start only.
	98	!------------------------------------------------------------------------------!
[792]	99
[828]	100	IMPLICIT NONE
[792]	101
[828]	102	INTEGER :: i, j, k
[790]	103
[828]	104
	105	!
	106	!-- Calculate collision efficiencies for fixed radius- and dissipation
	107	!-- classes
	108	IF ( collision_kernel(6:9) == 'fast' ) THEN
	109
	110	ALLOCATE( ckernel(1:radius_classes,1:radius_classes, &
	111	0:dissipation_classes), epsclass(1:dissipation_classes), &
	112	radclass(1:radius_classes) )
	113
	114	!
	115	!-- Calculate the radius class bounds with logarithmic distances
	116	!-- in the interval [1.0E-6, 2.0E-4] m
	117	rclass_lbound = LOG( 1.0E-6 )
	118	rclass_ubound = LOG( 2.0E-4 )
	119	radclass(1) = 1.0E-6
	120	DO i = 2, radius_classes
	121	radclass(i) = EXP( rclass_lbound + &
	122	( rclass_ubound - rclass_lbound ) * ( i-1.0 ) /&
	123	( radius_classes - 1.0 ) )
	124	! IF ( myid == 0 ) THEN
	125	! PRINT, 'i=', i, ' r = ', radclass(i)1.0E6
	126	! ENDIF
	127	ENDDO
	128	!
	129	!-- Collision routines expect radius to be in cm
	130	radclass = radclass * 100.0
	131
	132	!
	133	!-- Set the class bounds for dissipation in interval [0, 1000] cm2/s3
	134	DO i = 1, dissipation_classes
	135	epsclass(i) = 1000.0 * REAL( i ) / dissipation_classes
	136	! IF ( myid == 0 ) THEN
	137	! PRINT*, 'i=', i, ' eps = ', epsclass(i)
	138	! ENDIF
	139	ENDDO
	140	!
	141	!-- Calculate collision efficiencies of the Wang/ayala kernel
	142	ALLOCATE( ec(1:radius_classes,1:radius_classes), &
	143	ecf(1:radius_classes,1:radius_classes), &
	144	gck(1:radius_classes,1:radius_classes), &
	145	winf(1:radius_classes) )
	146
	147	DO k = 1, dissipation_classes
	148
	149	epsilon = epsclass(k)
	150	urms = 202.0 * ( epsilon / 400.0 )**( 1.0 / 3.0 )
	151
	152	CALL turbsd
	153	CALL turb_enhance_eff
	154	CALL effic
	155
	156	DO j = 1, radius_classes
	157	DO i = 1, radius_classes
	158	ckernel(i,j,k) = ec(i,j) * gck(i,j) * ecf(i,j)
	159	ENDDO
	160	ENDDO
	161
	162	ENDDO
	163
	164	!
	165	!-- Calculate collision efficiencies of the Hall kernel
	166	ALLOCATE( hkernel(1:radius_classes,1:radius_classes), &
	167	hwratio(1:radius_classes,1:radius_classes) )
	168
	169	CALL fallg
	170	CALL effic
	171
	172	DO j = 1, radius_classes
	173	DO i = 1, radius_classes
	174	hkernel(i,j) = pi * ( radclass(j) + radclass(i) )**2 &
	175	* ec(i,j) * ABS( winf(j) - winf(i) )
	176	ckernel(i,j,0) = hkernel(i,j) ! hall kernel stored on index 0
	177	ENDDO
	178	ENDDO
	179
	180	!
	181	!-- Test output of efficiencies
	182	IF ( j == -1 ) THEN
	183
	184	PRINT, '** Hall kernel'
	185	WRITE ( ,'(5X,20(F4.0,1X))' ) ( radclass(i)1.0E4, i = 1,radius_classes )
	186	DO j = 1, radius_classes
	187	WRITE ( *,'(F4.0,1X,20(F4.2,1X))' ) radclass(j), ( hkernel(i,j), i = 1,radius_classes )
	188	ENDDO
	189
	190	DO k = 1, dissipation_classes
	191	DO i = 1, radius_classes
	192	DO j = 1, radius_classes
	193	IF ( hkernel(i,j) == 0.0 ) THEN
	194	hwratio(i,j) = 9999999.9
	195	ELSE
	196	hwratio(i,j) = ckernel(i,j,k) / hkernel(i,j)
	197	ENDIF
	198	ENDDO
	199	ENDDO
	200
	201	PRINT, '** epsilon = ', epsclass(k)
	202	WRITE ( ,'(5X,20(F4.0,1X))' ) ( radclass(i)1.0E4, i = 1,radius_classes )
	203	DO j = 1, radius_classes
	204	! WRITE ( ,'(F4.0,1X,20(F4.2,1X))' ) radclass(j)1.0E4, ( ckernel(i,j,k), i = 1,radius_classes )
	205	WRITE ( ,'(F4.0,1X,20(F4.2,1X))' ) radclass(j)1.0E4, ( hwratio(i,j), i = 1,radius_classes )
	206	ENDDO
	207	ENDDO
	208
	209	ENDIF
	210
	211	DEALLOCATE( ec, ecf, epsclass, gck, hkernel, winf )
	212
	213	ckernel = ckernel * 1.0E-6 ! kernel is needed in m**3/s
	214
	215	ELSEIF( collision_kernel == 'hall' .OR. collision_kernel == 'wang' ) &
	216	THEN
	217	!
	218	!-- Initial settings for Hall- and Wang-Kernel
	219	!-- To be done: move here parts from turbsd, fallg, ecoll, etc.
	220	ENDIF
	221
	222	END SUBROUTINE init_kernels
	223
	224
[790]	225	!------------------------------------------------------------------------------!
[828]	226	! Calculation of collision kernels during each timestep and for each grid box
[790]	227	!------------------------------------------------------------------------------!
[828]	228	SUBROUTINE recalculate_kernel( i1, j1, k1 )
[790]	229
	230	USE arrays_3d
	231	USE cloud_parameters
	232	USE constants
[792]	233	USE cpulog
[790]	234	USE indices
[792]	235	USE interfaces
[790]	236	USE particle_attributes
	237
	238	IMPLICIT NONE
	239
[828]	240	INTEGER :: i, i1, j, j1, k1, pend, pstart
[790]	241
	242
[828]	243	pstart = prt_start_index(k1,j1,i1)
	244	pend = prt_start_index(k1,j1,i1) + prt_count(k1,j1,i1) - 1
	245	radius_classes = prt_count(k1,j1,i1)
[792]	246
[828]	247	ALLOCATE( ec(1:radius_classes,1:radius_classes), &
	248	radclass(1:radius_classes), winf(1:radius_classes) )
[790]	249
[828]	250	!
	251	!-- Store particle radii on the radclass array. Collision routines
	252	!-- expect radii to be in cm.
	253	radclass(1:radius_classes) = particles(pstart:pend)%radius * 100.0
[790]	254
[835]	255	IF ( wang_kernel ) THEN
	256	epsilon = diss(k1,j1,i1) * 1.0E4 ! dissipation rate in cm2/s-3
	257	ELSE
	258	epsilon = 0.0
	259	ENDIF
[828]	260	urms = 202.0 * ( epsilon / 400.0 )**( 0.33333333333 )
[790]	261
[828]	262	IF ( wang_kernel .AND. epsilon > 0.001 ) THEN
	263	!
	264	!-- Call routines to calculate efficiencies for the Wang kernel
	265	ALLOCATE( gck(1:radius_classes,1:radius_classes), &
	266	ecf(1:radius_classes,1:radius_classes) )
[790]	267
[828]	268	CALL turbsd
	269	CALL turb_enhance_eff
	270	CALL effic
[790]	271
[828]	272	DO j = 1, radius_classes
	273	DO i = 1, radius_classes
	274	ckernel(pstart+i-1,pstart+j-1,1) = ec(i,j) * gck(i,j) * ecf(i,j)
[790]	275	ENDDO
[828]	276	ENDDO
[790]	277
[828]	278	DEALLOCATE( gck, ecf )
[790]	279
	280	ELSE
[828]	281	!
	282	!-- Call routines to calculate efficiencies for the Hall kernel
[790]	283	CALL fallg
	284	CALL effic
	285
[828]	286	DO j = 1, radius_classes
	287	DO i = 1, radius_classes
	288	ckernel(pstart+i-1,pstart+j-1,1) = pi * &
	289	( radclass(j) + radclass(i) )**2 &
	290	* ec(i,j) * ABS( winf(j) - winf(i) )
[790]	291	ENDDO
	292	ENDDO
	293
	294	ENDIF
	295
[828]	296	ckernel = ckernel * 1.0E-6 ! kernel is needed in m**3/s
[790]	297
[828]	298	DEALLOCATE( ec, radclass, winf )
[790]	299
[828]	300	END SUBROUTINE recalculate_kernel
[790]	301
[828]	302
[790]	303	!------------------------------------------------------------------------------!
[828]	304	! Calculation of gck
	305	! This is from Aayala 2008b, page 37ff.
	306	! Necessary input parameters: water density, radii of droplets, air density,
	307	! air viscosity, turbulent dissipation rate, taylor microscale reynolds number,
	308	! gravitational acceleration --> to be replaced by PALM parameters
[790]	309	!------------------------------------------------------------------------------!
[792]	310	SUBROUTINE turbsd
[799]	311
[790]	312	USE constants
	313	USE cloud_parameters
	314	USE particle_attributes
	315	USE arrays_3d
	316
	317	IMPLICIT NONE
	318
[828]	319	INTEGER :: i, j
[790]	320
[828]	321	LOGICAL, SAVE :: first = .TRUE.
[790]	322
[828]	323	REAL :: ao, ao_gr, bbb, be, b1, b2, ccc, c1, c1_gr, c2, d1, d2, eta, &
	324	e1, e2, fao_gr, fr, grfin, lambda, lambda_re, lf, rc, rrp, &
	325	sst, tauk, tl, t2, tt, t1, vk, vrms1xy, vrms2xy, v1, v1v2xy, &
	326	v1xysq, v2, v2xysq, wrfin, wrgrav2, wrtur2xy, xx, yy, z
[799]	327
[828]	328	REAL, SAVE :: airdens, airvisc, anu, gravity, waterdens
[799]	329
[828]	330	REAL, DIMENSION(1:radius_classes) :: st, tau
[790]	331
[828]	332
[799]	333	!
[828]	334	!-- Initial assignment of constants
[799]	335	IF ( first ) THEN
[790]	336
[799]	337	first = .FALSE.
[828]	338	airvisc = 0.1818 ! dynamic viscosity in mg/cm*s
	339	airdens = 1.2250 ! air density in mg/cm**3
	340	waterdens = 1000.0 ! water density in mg/cm**3
	341	gravity = 980.6650 ! in cm/s**2
[799]	342	anu = airvisc/airdens ! kinetic viscosity in cm**2/s
[790]	343
[799]	344	ENDIF
[790]	345
[828]	346	lambda = urms * SQRT( 15.0 * anu / epsilon ) ! in cm
	347	lambda_re = urms*2 SQRT( 15.0 / epsilon / anu )
	348	tl = urms**2 / epsilon ! in s
	349	lf = 0.5 * urms**3 / epsilon ! in cm
	350	tauk = SQRT( anu / epsilon ) ! in s
	351	eta = ( anu3 / epsilon )0.25 ! in cm
	352	vk = eta / tauk ! in cm/s
[790]	353
[828]	354	ao = ( 11.0 + 7.0 * lambda_re ) / ( 205.0 + lambda_re )
	355	tt = SQRT( 2.0 * lambda_re / ( SQRT( 15.0 ) * ao ) ) * tauk ! in s
[799]	356
[828]	357	CALL fallg ! gives winf in cm/s
[790]	358
[828]	359	DO i = 1, radius_classes
	360	tau(i) = winf(i) / gravity ! in s
	361	st(i) = tau(i) / tauk
[790]	362	ENDDO
	363
[828]	364	!
	365	!-- Calculate wr (from Aayala 2008b, page 38f)
	366	z = tt / tl
	367	be = SQRT( 2.0 ) * lambda / lf
	368	bbb = SQRT( 1.0 - 2.0 * be**2 )
	369	d1 = ( 1.0 + bbb ) / ( 2.0 * bbb )
	370	e1 = lf * ( 1.0 + bbb ) * 0.5 ! in cm
	371	d2 = ( 1.0 - bbb ) * 0.5 / bbb
	372	e2 = lf * ( 1.0 - bbb ) * 0.5 ! in cm
	373	ccc = SQRT( 1.0 - 2.0 * z**2 )
	374	b1 = ( 1.0 + ccc ) * 0.5 / ccc
	375	c1 = tl * ( 1.0 + ccc ) * 0.5 ! in s
	376	b2 = ( 1.0 - ccc ) * 0.5 / ccc
	377	c2 = tl * ( 1.0 - ccc ) * 0.5 ! in s
[790]	378
[828]	379	DO i = 1, radius_classes
[790]	380
[828]	381	v1 = winf(i) ! in cm/s
	382	t1 = tau(i) ! in s
[790]	383
[828]	384	DO j = 1, i
	385	rrp = radclass(i) + radclass(j) ! radius in cm
	386	v2 = winf(j) ! in cm/s
	387	t2 = tau(j) ! in s
[790]	388
[828]	389	v1xysq = b1 * d1 * phi(c1,e1,v1,t1) - b1 * d2 * phi(c1,e2,v1,t1) &
	390	- b2 * d1 * phi(c2,e1,v1,t1) + b2 * d2 * phi(c2,e2,v1,t1)
	391	v1xysq = v1xysq * urms2 / t1 ! in cm2/s**2
	392	vrms1xy = SQRT( v1xysq ) ! in cm/s
[790]	393
[828]	394	v2xysq = b1 * d1 * phi(c1,e1,v2,t2) - b1 * d2 * phi(c1,e2,v2,t2) &
	395	- b2 * d1 * phi(c2,e1,v2,t2) + b2 * d2 * phi(c2,e2,v2,t2)
	396	v2xysq = v2xysq * urms2 / t2 ! in cm2/s**2
	397	vrms2xy = SQRT( v2xysq ) ! in cm/s
[790]	398
[828]	399	IF ( winf(i) >= winf(j) ) THEN
[799]	400	v1 = winf(i)
[790]	401	t1 = tau(i)
[799]	402	v2 = winf(j)
[790]	403	t2 = tau(j)
	404	ELSE
[799]	405	v1 = winf(j)
[790]	406	t1 = tau(j)
[799]	407	v2 = winf(i)
[790]	408	t2 = tau(i)
	409	ENDIF
	410
[828]	411	v1v2xy = b1 * d1 * zhi(c1,e1,v1,t1,v2,t2) - &
	412	b1 * d2 * zhi(c1,e2,v1,t1,v2,t2) - &
	413	b2 * d1 * zhi(c2,e1,v1,t1,v2,t2) + &
	414	b2 * d2* zhi(c2,e2,v1,t1,v2,t2)
	415	fr = d1 * EXP( -rrp / e1 ) - d2 * EXP( -rrp / e2 )
	416	v1v2xy = v1v2xy * fr * urms2 / tau(i) / tau(j) ! in cm2/s**2
	417	wrtur2xy = vrms1xy2 + vrms2xy2 - 2.0 * v1v2xy ! in cm2/s2
	418	IF ( wrtur2xy < 0.0 ) wrtur2xy = 0.0
	419	wrgrav2 = pi / 8.0 * ( winf(j) - winf(i) )**2
	420	wrfin = SQRT( ( 2.0 / pi ) * ( wrtur2xy + wrgrav2) ) ! in cm/s
[790]	421
[828]	422	!
	423	!-- Calculate gr
	424	IF ( st(j) > st(i) ) THEN
	425	sst = st(j)
[790]	426	ELSE
[828]	427	sst = st(i)
[790]	428	ENDIF
	429
[828]	430	xx = -0.1988 * sst*4 + 1.5275 sst*3 - 4.2942 sst**2 + &
	431	5.3406 * sst
	432	IF ( xx < 0.0 ) xx = 0.0
	433	yy = 0.1886 * EXP( 20.306 / lambda_re )
[790]	434
[828]	435	c1_gr = xx / ( gravity / vk * tauk )**yy
[790]	436
[828]	437	ao_gr = ao + ( pi / 8.0) * ( gravity / vk * tauk )**2
	438	fao_gr = 20.115 * SQRT( ao_gr / lambda_re )
	439	rc = SQRT( fao_gr * ABS( st(j) - st(i) ) ) * eta ! in cm
[790]	440
[828]	441	grfin = ( ( eta2 + rc2 ) / ( rrp2 + rc2) )*( c1_gr0.5 )
	442	IF ( grfin < 1.0 ) grfin = 1.0
[790]	443
[828]	444	gck(i,j) = 2.0 * pi * rrp*2 wrfin * grfin ! in cm**3/s
[790]	445	gck(j,i) = gck(i,j)
	446
	447	ENDDO
	448	ENDDO
	449
[828]	450	END SUBROUTINE turbsd
[790]	451
[828]	452
[790]	453	!------------------------------------------------------------------------------!
[828]	454	! phi as a function
[790]	455	!------------------------------------------------------------------------------!
[828]	456	REAL FUNCTION phi( a, b, vsett, tau0 )
[790]	457
	458	IMPLICIT NONE
	459
[828]	460	REAL :: a, aa1, b, tau0, vsett
[790]	461
[828]	462	aa1 = 1.0 / tau0 + 1.0 / a + vsett / b
	463	phi = 1.0 / aa1 - 0.5 * vsett / b / aa1**2 ! in s
[790]	464
[828]	465	END FUNCTION phi
[792]	466
[790]	467
	468	!------------------------------------------------------------------------------!
[828]	469	! zeta as a function
[790]	470	!------------------------------------------------------------------------------!
[828]	471	REAL FUNCTION zhi( a, b, vsett1, tau1, vsett2, tau2 )
[790]	472
	473	IMPLICIT NONE
	474
[828]	475	REAL :: a, aa1, aa2, aa3, aa4, aa5, aa6, b, tau1, tau2, vsett1, vsett2
[790]	476
[828]	477	aa1 = vsett2 / b - 1.0 / tau2 - 1.0 / a
	478	aa2 = vsett1 / b + 1.0 / tau1 + 1.0 / a
	479	aa3 = ( vsett1 - vsett2 ) / b + 1.0 / tau1 + 1.0 / tau2
	480	aa4 = ( vsett2 / b )2 - ( 1.0 / tau2 + 1.0 / a )2
	481	aa5 = vsett2 / b + 1.0 / tau2 + 1.0 / a
	482	aa6 = 1.0 / tau1 - 1.0 / a + ( 1.0 / tau2 + 1.0 / a) * vsett1 / vsett2
	483	zhi = (1.0 / aa1 - 1.0 / aa2 ) * ( vsett1 - vsett2 ) * 0.5 / b / aa3**2 &
	484	+ (4.0 / aa4 - 1.0 / aa52 - 1.0 / aa12 ) * vsett2 * 0.5 / b /aa6&
	485	+ (2.0 * ( b / aa2 - b / aa1 ) - vsett1 / aa22 + vsett2 / aa12 )&
	486	* 0.5 / b / aa3 ! in s**2
[799]	487
[828]	488	END FUNCTION zhi
[790]	489
[828]	490
[790]	491	!------------------------------------------------------------------------------!
[828]	492	! Calculation of terminal velocity winf
[790]	493	!------------------------------------------------------------------------------!
[828]	494	SUBROUTINE fallg
[790]	495
	496	USE constants
	497	USE cloud_parameters
	498	USE particle_attributes
	499	USE arrays_3d
	500
[828]	501	IMPLICIT NONE
[790]	502
[828]	503	INTEGER :: i, j
[790]	504
[828]	505	LOGICAL, SAVE :: first = .TRUE.
[790]	506
[828]	507	REAL, SAVE :: cunh, eta, grav, phy, py, rhoa, rhow, sigma, stb, stok, &
	508	t0, xlamb
[790]	509
[828]	510	REAL :: bond, x, xrey, y
[799]	511
[828]	512	REAL, DIMENSION(1:7), SAVE :: b
	513	REAL, DIMENSION(1:6), SAVE :: c
[799]	514
	515	!
[828]	516	!-- Initial assignment of constants
	517	IF ( first ) THEN
[799]	518
[828]	519	first = .FALSE.
	520	b = (/ -0.318657E1, 0.992696E0, -0.153193E-2, -0.987059E-3, &
	521	-0.578878E-3, 0.855176E-4, -0.327815E-5 /)
	522	c = (/ -0.500015E1, 0.523778E1, -0.204914E1, 0.475294E0, &
	523	-0.542819E-1, 0.238449E-2 /)
[790]	524
[828]	525	eta = 1.818E-4 ! in poise = g/(cm s)
	526	xlamb = 6.62E-6 ! in cm
	527	rhow = 1.0 ! in g/cm**3
	528	rhoa = 1.225E-3 ! in g/cm**3
	529	grav = 980.665 ! in cm/s**2
	530	cunh = 1.257 * xlamb ! in cm
	531	t0 = 273.15 ! in K
	532	sigma = 76.1 - 0.155 * ( 293.15 - t0 ) ! in N/m = g/s**2
	533	stok = 2.0 * grav * ( rhow - rhoa ) / ( 9.0 * eta ) ! in 1/(cm s)
	534	stb = 32.0 * rhoa * ( rhow - rhoa) * grav / (3.0 * eta * eta)
	535	! in 1/cm**3
	536	phy = sigma*3 rhoa2 / ( eta4 * grav * ( rhow - rhoa ) )
	537	py = phy**( 1.0 / 6.0 )
[790]	538
[828]	539	ENDIF
[790]	540
[828]	541	DO j = 1, radius_classes
[790]	542
[828]	543	IF ( radclass(j) <= 1.0E-3 ) THEN
[799]	544
[828]	545	winf(j) = stok * ( radclass(j)*2 + cunh radclass(j) ) ! in cm/s
[790]	546
[828]	547	ELSEIF ( radclass(j) > 1.0E-3 .AND. radclass(j) <= 5.35E-2 ) THEN
[790]	548
[828]	549	x = LOG( stb * radclass(j)**3 )
	550	y = 0.0
[790]	551
[828]	552	DO i = 1, 7
	553	y = y + b(i) * x**(i-1)
	554	ENDDO
[790]	555
[828]	556	xrey = ( 1.0 + cunh / radclass(j) ) * EXP( y )
	557	winf(j) = xrey * eta / ( 2.0 * rhoa * radclass(j) ) ! in cm/s
[790]	558
[828]	559	ELSEIF ( radclass(j) > 5.35E-2 ) THEN
[790]	560
[828]	561	IF ( radclass(j) > 0.35 ) THEN
	562	bond = grav * ( rhow - rhoa ) * 0.35**2 / sigma
	563	ELSE
	564	bond = grav * ( rhow - rhoa ) * radclass(j)**2 / sigma
	565	ENDIF
[790]	566
[828]	567	x = LOG( 16.0 * bond * py / 3.0 )
	568	y = 0.0
[790]	569
[828]	570	DO i = 1, 6
	571	y = y + c(i) * x**(i-1)
	572	ENDDO
[790]	573
[828]	574	xrey = py * EXP( y )
[790]	575
[828]	576	IF ( radclass(j) > 0.35 ) THEN
	577	winf(j) = xrey * eta / ( 2.0 * rhoa * 0.35 ) ! in cm/s
	578	ELSE
	579	winf(j) = xrey * eta / ( 2.0 * rhoa * radclass(j) ) ! in cm/s
	580	ENDIF
[790]	581
[828]	582	ENDIF
[790]	583
[828]	584	ENDDO
[790]	585
[828]	586	END SUBROUTINE fallg
[790]	587
[828]	588
[790]	589	!------------------------------------------------------------------------------!
[828]	590	! Calculation of collision efficencies for the Hall kernel
[790]	591	!------------------------------------------------------------------------------!
[828]	592	SUBROUTINE effic
[790]	593
[828]	594	USE arrays_3d
	595	USE cloud_parameters
	596	USE constants
	597	USE particle_attributes
[790]	598
[828]	599	IMPLICIT NONE
[790]	600
[828]	601	INTEGER :: i, iq, ir, j, k, kk
[790]	602
[828]	603	INTEGER, DIMENSION(:), ALLOCATABLE :: ira
[790]	604
[828]	605	LOGICAL, SAVE :: first = .TRUE.
[790]	606
[828]	607	REAL :: ek, particle_radius, pp, qq, rq
[790]	608
[828]	609	REAL, DIMENSION(1:21), SAVE :: rat
	610	REAL, DIMENSION(1:15), SAVE :: r0
	611	REAL, DIMENSION(1:15,1:21), SAVE :: ecoll
[790]	612
[792]	613	!
[828]	614	!-- Initial assignment of constants
	615	IF ( first ) THEN
[790]	616
[792]	617	first = .FALSE.
[828]	618	r0 = (/ 6.0, 8.0, 10.0, 15.0, 20.0, 25.0, 30.0, 40.0, 50.0, 60., &
	619	70.0, 100.0, 150.0, 200.0, 300.0 /)
	620	rat = (/ 0.00, 0.05, 0.10, 0.15, 0.20, 0.25, 0.30, 0.35, 0.40, 0.45, &
	621	0.50, 0.55, 0.60, 0.65, 0.70, 0.75, 0.80, 0.85, 0.90, 0.95, &
	622	1.00 /)
[790]	623
[828]	624	ecoll(:,1) = (/0.001, 0.001, 0.001, 0.001, 0.001, 0.001, 0.001, &
	625	0.001, 0.001, 0.001, 0.001, 0.001, 0.001, 0.001, 0.001/)
	626	ecoll(:,2) = (/0.003, 0.003, 0.003, 0.004, 0.005, 0.005, 0.005, &
	627	0.010, 0.100, 0.050, 0.200, 0.500, 0.770, 0.870, 0.970/)
	628	ecoll(:,3) = (/0.007, 0.007, 0.007, 0.008, 0.009, 0.010, 0.010, &
	629	0.070, 0.400, 0.430, 0.580, 0.790, 0.930, 0.960, 1.000/)
	630	ecoll(:,4) = (/0.009, 0.009, 0.009, 0.012, 0.015, 0.010, 0.020, &
	631	0.280, 0.600, 0.640, 0.750, 0.910, 0.970, 0.980, 1.000/)
	632	ecoll(:,5) = (/0.014, 0.014, 0.014, 0.015, 0.016, 0.030, 0.060, &
	633	0.500, 0.700, 0.770, 0.840, 0.950, 0.970, 1.000, 1.000/)
	634	ecoll(:,6) = (/0.017, 0.017, 0.017, 0.020, 0.022, 0.060, 0.100, &
	635	0.620, 0.780, 0.840, 0.880, 0.950, 1.000, 1.000, 1.000/)
	636	ecoll(:,7) = (/0.030, 0.030, 0.024, 0.022, 0.032, 0.062, 0.200, &
	637	0.680, 0.830, 0.870, 0.900, 0.950, 1.000, 1.000, 1.000/)
	638	ecoll(:,8) = (/0.025, 0.025, 0.025, 0.036, 0.043, 0.130, 0.270, &
	639	0.740, 0.860, 0.890, 0.920, 1.000, 1.000, 1.000, 1.000/)
	640	ecoll(:,9) = (/0.027, 0.027, 0.027, 0.040, 0.052, 0.200, 0.400, &
	641	0.780, 0.880, 0.900, 0.940, 1.000, 1.000, 1.000, 1.000/)
	642	ecoll(:,10)= (/0.030, 0.030, 0.030, 0.047, 0.064, 0.250, 0.500, &
	643	0.800, 0.900, 0.910, 0.950, 1.000, 1.000, 1.000, 1.000/)
	644	ecoll(:,11)= (/0.040, 0.040, 0.033, 0.037, 0.068, 0.240, 0.550, &
	645	0.800, 0.900, 0.910, 0.950, 1.000, 1.000, 1.000, 1.000/)
	646	ecoll(:,12)= (/0.035, 0.035, 0.035, 0.055, 0.079, 0.290, 0.580, &
	647	0.800, 0.900, 0.910, 0.950, 1.000, 1.000, 1.000, 1.000/)
	648	ecoll(:,13)= (/0.037, 0.037, 0.037, 0.062, 0.082, 0.290, 0.590, &
	649	0.780, 0.900, 0.910, 0.950, 1.000, 1.000, 1.000, 1.000/)
	650	ecoll(:,14)= (/0.037, 0.037, 0.037, 0.060, 0.080, 0.290, 0.580, &
	651	0.770, 0.890, 0.910, 0.950, 1.000, 1.000, 1.000, 1.000/)
	652	ecoll(:,15)= (/0.037, 0.037, 0.037, 0.041, 0.075, 0.250, 0.540, &
	653	0.760, 0.880, 0.920, 0.950, 1.000, 1.000, 1.000, 1.000/)
	654	ecoll(:,16)= (/0.037, 0.037, 0.037, 0.052, 0.067, 0.250, 0.510, &
	655	0.770, 0.880, 0.930, 0.970, 1.000, 1.000, 1.000, 1.000/)
	656	ecoll(:,17)= (/0.037, 0.037, 0.037, 0.047, 0.057, 0.250, 0.490, &
	657	0.770, 0.890, 0.950, 1.000, 1.000, 1.000, 1.000, 1.000/)
	658	ecoll(:,18)= (/0.036, 0.036, 0.036, 0.042, 0.048, 0.230, 0.470, &
	659	0.780, 0.920, 1.000, 1.020, 1.020, 1.020, 1.020, 1.020/)
	660	ecoll(:,19)= (/0.040, 0.040, 0.035, 0.033, 0.040, 0.112, 0.450, &
	661	0.790, 1.010, 1.030, 1.040, 1.040, 1.040, 1.040, 1.040/)
	662	ecoll(:,20)= (/0.033, 0.033, 0.033, 0.033, 0.033, 0.119, 0.470, &
	663	0.950, 1.300, 1.700, 2.300, 2.300, 2.300, 2.300, 2.300/)
	664	ecoll(:,21)= (/0.027, 0.027, 0.027, 0.027, 0.027, 0.125, 0.520, &
	665	1.400, 2.300, 3.000, 4.000, 4.000, 4.000, 4.000, 4.000/)
	666	ENDIF
[790]	667
[792]	668	!
[828]	669	!-- Calculate the radius class index of particles with respect to array r
	670	ALLOCATE( ira(1:radius_classes) )
	671	DO j = 1, radius_classes
	672	particle_radius = radclass(j) * 1.0E4 ! in microm
	673	DO k = 1, 15
	674	IF ( particle_radius < r0(k) ) THEN
	675	ira(j) = k
	676	EXIT
	677	ENDIF
	678	ENDDO
	679	IF ( particle_radius >= r0(15) ) ira(j) = 16
	680	ENDDO
[790]	681
[792]	682	!
[828]	683	!-- Two-dimensional linear interpolation of the collision efficiency.
	684	!-- Radius has to be in Âµm
	685	DO j = 1, radius_classes
	686	DO i = 1, j
[792]	687
[828]	688	ir = ira(j)
	689	rq = radclass(i) / radclass(j)
	690	iq = INT( rq * 20 ) + 1
	691	iq = MAX( iq , 2)
[792]	692
[828]	693	IF ( ir < 16 ) THEN
	694	IF ( ir >= 2 ) THEN
	695	pp = ( ( radclass(j) * 1.0E04 ) - r0(ir-1) ) / &
	696	( r0(ir) - r0(ir-1) )
	697	qq = ( rq- rat(iq-1) ) / ( rat(iq) - rat(iq-1) )
	698	ec(j,i) = ( 1.0-pp ) * ( 1.0-qq ) * ecoll(ir-1,iq-1) &
	699	+ pp * ( 1.0-qq ) * ecoll(ir,iq-1) &
	700	+ qq * ( 1.0-pp ) * ecoll(ir-1,iq) &
	701	+ pp * qq * ecoll(ir,iq)
	702	ELSE
	703	qq = ( rq - rat(iq-1) ) / ( rat(iq) - rat(iq-1) )
	704	ec(j,i) = (1.0-qq) * ecoll(1,iq-1) + qq * ecoll(1,iq)
	705	ENDIF
	706	ELSE
	707	qq = ( rq - rat(iq-1) ) / ( rat(iq) - rat(iq-1) )
	708	ek = ( 1.0 - qq ) * ecoll(15,iq-1) + qq * ecoll(15,iq)
	709	ec(j,i) = MIN( ek, 1.0 )
	710	ENDIF
[792]	711
[828]	712	ec(i,j) = ec(j,i)
	713	IF ( ec(i,j) < 1.0E-20 ) ec(i,j) = 0.0
[792]	714
[828]	715	ENDDO
	716	ENDDO
[792]	717
[828]	718	DEALLOCATE( ira )
[792]	719
[828]	720	END SUBROUTINE effic
[792]	721
	722
[790]	723	!------------------------------------------------------------------------------!
[828]	724	! Calculation of enhancement factor for collision efficencies due to turbulence
[790]	725	!------------------------------------------------------------------------------!
[828]	726	SUBROUTINE turb_enhance_eff
[790]	727
	728	USE constants
	729	USE cloud_parameters
	730	USE particle_attributes
	731	USE arrays_3d
	732
[828]	733	IMPLICIT NONE
[790]	734
[828]	735	INTEGER :: i, ik, iq, ir, j, k, kk
[790]	736
[828]	737	INTEGER, DIMENSION(:), ALLOCATABLE :: ira
[790]	738
[828]	739	REAL :: particle_radius, pp, qq, rq, x1, x2, x3, y1, y2, y3
[790]	740
[828]	741	LOGICAL, SAVE :: first = .TRUE.
[799]	742
[828]	743	REAL, DIMENSION(1:11), SAVE :: rat
	744	REAL, DIMENSION(1:7), SAVE :: r0
	745	REAL, DIMENSION(1:7,1:11), SAVE :: ecoll_100, ecoll_400
[799]	746
	747	!
[828]	748	!-- Initial assignment of constants
	749	IF ( first ) THEN
[799]	750
[828]	751	first = .FALSE.
[799]	752
[828]	753	r0 = (/ 10.0, 20.0, 30.0, 40.0, 50.0, 60.0, 100.0 /)
	754	rat = (/ 0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0 /)
	755	!
	756	!-- In 100 cm^2/s^3
	757	ecoll_100(:,1) = (/1.74, 1.74, 1.773, 1.49, 1.207, 1.207, 1.0 /)
	758	ecoll_100(:,2) = (/1.46, 1.46, 1.421, 1.245, 1.069, 1.069, 1.0 /)
	759	ecoll_100(:,3) = (/1.32, 1.32, 1.245, 1.123, 1.000, 1.000, 1.0 /)
	760	ecoll_100(:,4) = (/1.250, 1.250, 1.148, 1.087, 1.025, 1.025, 1.0 /)
	761	ecoll_100(:,5) = (/1.186, 1.186, 1.066, 1.060, 1.056, 1.056, 1.0 /)
	762	ecoll_100(:,6) = (/1.045, 1.045, 1.000, 1.014, 1.028, 1.028, 1.0 /)
	763	ecoll_100(:,7) = (/1.070, 1.070, 1.030, 1.038, 1.046, 1.046, 1.0 /)
	764	ecoll_100(:,8) = (/1.000, 1.000, 1.054, 1.042, 1.029, 1.029, 1.0 /)
	765	ecoll_100(:,9) = (/1.223, 1.223, 1.117, 1.069, 1.021, 1.021, 1.0 /)
	766	ecoll_100(:,10)= (/1.570, 1.570, 1.244, 1.166, 1.088, 1.088, 1.0 /)
	767	ecoll_100(:,11)= (/20.3, 20.3, 14.6 , 8.61, 2.60, 2.60 , 1.0 /)
	768	!
	769	!-- In 400 cm^2/s^3
	770	ecoll_400(:,1) = (/4.976, 4.976, 3.593, 2.519, 1.445, 1.445, 1.0 /)
	771	ecoll_400(:,2) = (/2.984, 2.984, 2.181, 1.691, 1.201, 1.201, 1.0 /)
	772	ecoll_400(:,3) = (/1.988, 1.988, 1.475, 1.313, 1.150, 1.150, 1.0 /)
	773	ecoll_400(:,4) = (/1.490, 1.490, 1.187, 1.156, 1.126, 1.126, 1.0 /)
	774	ecoll_400(:,5) = (/1.249, 1.249, 1.088, 1.090, 1.092, 1.092, 1.0 /)
	775	ecoll_400(:,6) = (/1.139, 1.139, 1.130, 1.091, 1.051, 1.051, 1.0 /)
	776	ecoll_400(:,7) = (/1.220, 1.220, 1.190, 1.138, 1.086, 1.086, 1.0 /)
	777	ecoll_400(:,8) = (/1.325, 1.325, 1.267, 1.165, 1.063, 1.063, 1.0 /)
	778	ecoll_400(:,9) = (/1.716, 1.716, 1.345, 1.223, 1.100, 1.100, 1.0 /)
	779	ecoll_400(:,10)= (/3.788, 3.788, 1.501, 1.311, 1.120, 1.120, 1.0 /)
	780	ecoll_400(:,11)= (/36.52, 36.52, 19.16, 22.80, 26.0, 26.0, 1.0 /)
[799]	781
[828]	782	ENDIF
[790]	783
[828]	784	!
	785	!-- Calculate the radius class index of particles with respect to array r0
	786	ALLOCATE( ira(1:radius_classes) )
[790]	787
[828]	788	DO j = 1, radius_classes
	789	particle_radius = radclass(j) * 1.0E4 ! in microm
	790	DO k = 1, 7
	791	IF ( particle_radius < r0(k) ) THEN
	792	ira(j) = k
	793	EXIT
	794	ENDIF
	795	ENDDO
	796	IF ( particle_radius >= r0(7) ) ira(j) = 8
	797	ENDDO
[799]	798
	799	!
[828]	800	!-- Two-dimensional linear interpolation of the collision efficiencies
	801	DO j = 1, radius_classes
	802	DO i = 1, j
[799]	803
[828]	804	ir = ira(j)
	805	rq = radclass(i) / radclass(j)
[799]	806
[828]	807	DO kk = 2, 11
	808	IF ( rq <= rat(kk) ) THEN
	809	iq = kk
	810	EXIT
	811	ENDIF
	812	ENDDO
[790]	813
[828]	814	y1 = 1.0 ! 0 cm2/s3
	815	!
	816	!-- 100 cm2/s3, 400 cm2/s3
	817	IF ( ir < 8 ) THEN
	818	IF ( ir >= 2 ) THEN
	819	pp = ( radclass(j)*1.0E4 - r0(ir-1) ) / ( r0(ir) - r0(ir-1) )
	820	qq = ( rq - rat(iq-1) ) / ( rat(iq) - rat(iq-1) )
	821	y2 = ( 1.0-pp ) * ( 1.0-qq ) * ecoll_100(ir-1,iq-1) + &
	822	pp * ( 1.0-qq ) * ecoll_100(ir,iq-1) + &
	823	qq * ( 10.-pp ) * ecoll_100(ir-1,iq) + &
	824	pp * qq * ecoll_100(ir,iq)
	825	y3 = ( 1.0-pp ) * ( 1.0-qq ) * ecoll_400(ir-1,iq-1) + &
	826	pp * ( 1.0-qq ) * ecoll_400(ir,iq-1) + &
	827	qq * ( 1.0-pp ) * ecoll_400(ir-1,iq) + &
	828	pp * qq * ecoll_400(ir,iq)
	829	ELSE
	830	qq = ( rq - rat(iq-1) ) / ( rat(iq) - rat(iq-1) )
	831	y2 = ( 1.0-qq ) * ecoll_100(1,iq-1) + qq * ecoll_100(1,iq)
	832	y3 = ( 1.0-qq ) * ecoll_400(1,iq-1) + qq * ecoll_400(1,iq)
	833	ENDIF
	834	ELSE
	835	qq = ( rq - rat(iq-1) ) / ( rat(iq) - rat(iq-1) )
	836	y2 = ( 1.0-qq ) * ecoll_100(7,iq-1) + qq * ecoll_100(7,iq)
	837	y3 = ( 1.0-qq ) * ecoll_400(7,iq-1) + qq * ecoll_400(7,iq)
	838	ENDIF
	839	!
	840	!-- Linear interpolation of dissipation rate in cm2/s3
	841	IF ( epsilon <= 100.0 ) THEN
	842	ecf(j,i) = ( epsilon - 100.0 ) / ( 0.0 - 100.0 ) * y1 &
	843	+ ( epsilon - 0.0 ) / ( 100.0 - 0.0 ) * y2
	844	ELSEIF ( epsilon <= 600.0 ) THEN
	845	ecf(j,i) = ( epsilon - 400.0 ) / ( 100.0 - 400.0 ) * y2 &
	846	+ ( epsilon - 100.0 ) / ( 400.0 - 100.0 ) * y3
	847	ELSE
	848	ecf(j,i) = ( 600.0 - 400.0 ) / ( 100.0 - 400.0 ) * y2 &
	849	+ ( 600.0 - 100.0 ) / ( 400.0 - 100.0 ) * y3
	850	ENDIF
[790]	851
[828]	852	IF ( ecf(j,i) < 1.0 ) ecf(j,i) = 1.0
[790]	853
[828]	854	ecf(i,j) = ecf(j,i)
[790]	855
[828]	856	ENDDO
	857	ENDDO
[790]	858
[828]	859	END SUBROUTINE turb_enhance_eff
[790]	860
[849]	861
	862
	863	SUBROUTINE collision_efficiency_rogers( mean_r, r, e)
	864	!------------------------------------------------------------------------------!
	865	! Collision efficiencies from table 8.2 in Rogers and Yau (1989, 3rd edition).
	866	! Values are calculated from table by bilinear interpolation.
	867	!------------------------------------------------------------------------------!
	868
	869	IMPLICIT NONE
	870
	871	INTEGER :: i, j, k
	872
	873	LOGICAL, SAVE :: first = .TRUE.
	874
	875	REAL :: aa, bb, cc, dd, dx, dy, e, gg, mean_r, mean_rm, r, &
	876	rm, x, y
	877
	878	REAL, DIMENSION(1:9), SAVE :: collected_r = 0.0
	879	REAL, DIMENSION(1:19), SAVE :: collector_r = 0.0
	880	REAL, DIMENSION(1:9,1:19), SAVE :: ef = 0.0
	881
	882	mean_rm = mean_r * 1.0E06
	883	rm = r * 1.0E06
	884
	885	IF ( first ) THEN
	886
	887	collected_r = (/ 2.0, 3.0, 4.0, 6.0, 8.0, 10.0, 15.0, 20.0, 25.0 /)
	888	collector_r = (/ 10.0, 20.0, 30.0, 40.0, 50.0, 60.0, 80.0, 100.0, &
	889	150.0, 200.0, 300.0, 400.0, 500.0, 600.0, 1000.0, &
	890	1400.0, 1800.0, 2400.0, 3000.0 /)
	891
	892	ef(:,1) = (/0.017, 0.027, 0.037, 0.052, 0.052, 0.052, 0.052, 0.0, &
	893	0.0 /)
	894	ef(:,2) = (/0.001, 0.016, 0.027, 0.060, 0.12, 0.17, 0.17, 0.17, 0.0 /)
	895	ef(:,3) = (/0.001, 0.001, 0.02, 0.13, 0.28, 0.37, 0.54, 0.55, 0.47/)
	896	ef(:,4) = (/0.001, 0.001, 0.02, 0.23, 0.4, 0.55, 0.7, 0.75, 0.75/)
	897	ef(:,5) = (/0.01, 0.01, 0.03, 0.3, 0.4, 0.58, 0.73, 0.75, 0.79/)
	898	ef(:,6) = (/0.01, 0.01, 0.13, 0.38, 0.57, 0.68, 0.80, 0.86, 0.91/)
	899	ef(:,7) = (/0.01, 0.085, 0.23, 0.52, 0.68, 0.76, 0.86, 0.92, 0.95/)
	900	ef(:,8) = (/0.01, 0.14, 0.32, 0.60, 0.73, 0.81, 0.90, 0.94, 0.96/)
	901	ef(:,9) = (/0.025, 0.25, 0.43, 0.66, 0.78, 0.83, 0.92, 0.95, 0.96/)
	902	ef(:,10)= (/0.039, 0.3, 0.46, 0.69, 0.81, 0.87, 0.93, 0.95, 0.96/)
	903	ef(:,11)= (/0.095, 0.33, 0.51, 0.72, 0.82, 0.87, 0.93, 0.96, 0.97/)
	904	ef(:,12)= (/0.098, 0.36, 0.51, 0.73, 0.83, 0.88, 0.93, 0.96, 0.97/)
	905	ef(:,13)= (/0.1, 0.36, 0.52, 0.74, 0.83, 0.88, 0.93, 0.96, 0.97/)
	906	ef(:,14)= (/0.17, 0.4, 0.54, 0.72, 0.83, 0.88, 0.94, 0.98, 1.0 /)
	907	ef(:,15)= (/0.15, 0.37, 0.52, 0.74, 0.82, 0.88, 0.94, 0.98, 1.0 /)
	908	ef(:,16)= (/0.11, 0.34, 0.49, 0.71, 0.83, 0.88, 0.94, 0.95, 1.0 /)
	909	ef(:,17)= (/0.08, 0.29, 0.45, 0.68, 0.8, 0.86, 0.96, 0.94, 1.0 /)
	910	ef(:,18)= (/0.04, 0.22, 0.39, 0.62, 0.75, 0.83, 0.92, 0.96, 1.0 /)
	911	ef(:,19)= (/0.02, 0.16, 0.33, 0.55, 0.71, 0.81, 0.90, 0.94, 1.0 /)
	912
	913	ENDIF
	914
	915	DO k = 1, 8
	916	IF ( collected_r(k) <= mean_rm ) i = k
	917	ENDDO
	918
	919	DO k = 1, 18
	920	IF ( collector_r(k) <= rm ) j = k
	921	ENDDO
	922
	923	IF ( rm < 10.0 ) THEN
	924	e = 0.0
	925	ELSEIF ( mean_rm < 2.0 ) THEN
	926	e = 0.001
	927	ELSEIF ( mean_rm >= 25.0 ) THEN
	928	IF( j <= 2 ) e = 0.0
	929	IF( j == 3 ) e = 0.47
	930	IF( j == 4 ) e = 0.8
	931	IF( j == 5 ) e = 0.9
	932	IF( j >=6 ) e = 1.0
	933	ELSEIF ( rm >= 3000.0 ) THEN
	934	IF( i == 1 ) e = 0.02
	935	IF( i == 2 ) e = 0.16
	936	IF( i == 3 ) e = 0.33
	937	IF( i == 4 ) e = 0.55
	938	IF( i == 5 ) e = 0.71
	939	IF( i == 6 ) e = 0.81
	940	IF( i == 7 ) e = 0.90
	941	IF( i >= 8 ) e = 0.94
	942	ELSE
	943	x = mean_rm - collected_r(i)
	944	y = rm - collector_r(j)
	945	dx = collected_r(i+1) - collected_r(i)
	946	dy = collector_r(j+1) - collector_r(j)
	947	aa = x2 + y2
	948	bb = ( dx - x )2 + y2
	949	cc = x2 + ( dy - y )2
	950	dd = ( dx - x )2 + ( dy - y )2
	951	gg = aa + bb + cc + dd
	952
	953	e = ( (gg-aa)ef(i,j) + (gg-bb)ef(i+1,j) + (gg-cc)*ef(i,j+1) + &
	954	(gg-dd)ef(i+1,j+1) ) / (3.0gg)
	955	ENDIF
	956
	957	END SUBROUTINE collision_efficiency_rogers
	958
[825]	959	END MODULE lpm_collision_kernels_mod

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