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sbcblk_algo_ecmwf.F90 in NEMO/branches/2019/dev_r11085_ASINTER-05_Brodeau_Advanced_Bulk/src/OCE/SBC – NEMO

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source: NEMO/branches/2019/dev_r11085_ASINTER-05_Brodeau_Advanced_Bulk/src/OCE/SBC/sbcblk_algo_ecmwf.F90 @ 11845

Last change on this file since 11845 was 11845, checked in by laurent, 4 years ago
Improving syntax consistency
Property svn:keywords set to `Id`
File size: 25.0 KB

Rev	Line
[6723]	1	MODULE sbcblk_algo_ecmwf
	2	!!======================================================================
[11111]	3	!! * MODULE sbcblk_algo_ecmwf *
	4	!! Computes:
[6723]	5	!! * bulk transfer coefficients C_D, C_E and C_H
	6	!! * air temp. and spec. hum. adjusted from zt (2m) to zu (10m) if needed
	7	!! * the effective bulk wind speed at 10m U_blk
	8	!! => all these are used in bulk formulas in sbcblk.F90
	9	!!
[11111]	10	!! Using the bulk formulation/param. of IFS of ECMWF (cycle 40r1)
[6723]	11	!! based on IFS doc (avaible online on the ECMWF's website)
	12	!!
	13	!! Routine turb_ecmwf maintained and developed in AeroBulk
[11111]	14	!! (https://github.com/brodeau/aerobulk)
[6723]	15	!!
[11215]	16	!! ** Author: L. Brodeau, June 2019 / AeroBulk (https://github.com/brodeau/aerobulk)
[6723]	17	!!----------------------------------------------------------------------
[6727]	18	!! History : 4.0 ! 2016-02 (L.Brodeau) Original code
[6723]	19	!!----------------------------------------------------------------------
[6727]	20
	21	!!----------------------------------------------------------------------
[6723]	22	!! turb_ecmwf : computes the bulk turbulent transfer coefficients
	23	!! adjusts t_air and q_air from zt to zu m
	24	!! returns the effective bulk wind speed at 10m
	25	!!----------------------------------------------------------------------
	26	USE oce ! ocean dynamics and tracers
	27	USE dom_oce ! ocean space and time domain
	28	USE phycst ! physical constants
	29	USE iom ! I/O manager library
	30	USE lib_mpp ! distribued memory computing library
	31	USE in_out_manager ! I/O manager
	32	USE prtctl ! Print control
	33	USE sbcwave, ONLY : cdn_wave ! wave module
[9570]	34	#if defined key_si3 \|\| defined key_cice
[6723]	35	USE sbc_ice ! Surface boundary condition: ice fields
	36	#endif
	37	USE lib_fortran ! to use key_nosignedzero
	38
	39	USE sbc_oce ! Surface boundary condition: ocean fields
[11215]	40	USE sbcblk_phy ! all thermodynamics functions, rho_air, q_sat, etc... !LB
[11615]	41	USE sbcblk_skin_ecmwf ! cool-skin/warm layer scheme !LB
[6723]	42
	43	IMPLICIT NONE
	44	PRIVATE
	45
[11772]	46	PUBLIC :: ECMWF_INIT, TURB_ECMWF
[6723]	47
[11785]	48	!! ECMWF own values for given constants, taken form IFS documentation...
[6723]	49	REAL(wp), PARAMETER :: charn0 = 0.018 ! Charnock constant (pretty high value here !!!
	50	! ! => Usually 0.011 for moderate winds)
	51	REAL(wp), PARAMETER :: zi0 = 1000. ! scale height of the atmospheric boundary layer...1
	52	REAL(wp), PARAMETER :: Beta0 = 1. ! gustiness parameter ( = 1.25 in COAREv3)
	53	REAL(wp), PARAMETER :: alpha_M = 0.11 ! For roughness length (smooth surface term)
	54	REAL(wp), PARAMETER :: alpha_H = 0.40 ! (Chapter 3, p.34, IFS doc Cy31r1)
	55	REAL(wp), PARAMETER :: alpha_Q = 0.62 !
[11111]	56
[11772]	57	INTEGER , PARAMETER :: nb_itt = 10 ! number of itterations
[11111]	58
[6723]	59	!!----------------------------------------------------------------------
	60	CONTAINS
	61
[11772]	62
	63	SUBROUTINE ecmwf_init(l_use_cs, l_use_wl)
	64	!!---------------------------------------------------------------------
	65	!! * FUNCTION ecmwf_init *
	66	!!
	67	!! INPUT :
	68	!! -------
	69	!! * l_use_cs : use the cool-skin parameterization
	70	!! * l_use_wl : use the warm-layer parameterization
	71	!!---------------------------------------------------------------------
	72	LOGICAL , INTENT(in) :: l_use_cs ! use the cool-skin parameterization
	73	LOGICAL , INTENT(in) :: l_use_wl ! use the warm-layer parameterization
	74	INTEGER :: ierr
	75	!!---------------------------------------------------------------------
	76	IF ( l_use_wl ) THEN
	77	ierr = 0
	78	ALLOCATE ( dT_wl(jpi,jpj), Hz_wl(jpi,jpj), STAT=ierr )
[11816]	79	IF( ierr > 0 ) CALL ctl_stop( ' ECMWF_INIT => allocation of dT_wl & Hz_wl failed!' )
[11772]	80	dT_wl(:,:) = 0._wp
	81	Hz_wl(:,:) = rd0 ! (rd0, constant, = 3m is default for Zeng & Beljaars)
	82	END IF
	83	IF ( l_use_cs ) THEN
	84	ierr = 0
	85	ALLOCATE ( dT_cs(jpi,jpj), STAT=ierr )
[11816]	86	IF( ierr > 0 ) CALL ctl_stop( ' ECMWF_INIT => allocation of dT_cs failed!' )
[11772]	87	dT_cs(:,:) = -0.25_wp ! First guess of skin correction
	88	END IF
	89	END SUBROUTINE ecmwf_init
	90
	91
	92
	93	SUBROUTINE turb_ecmwf( kt, zt, zu, T_s, t_zt, q_s, q_zt, U_zu, l_use_cs, l_use_wl, &
	94	& Cd, Ch, Ce, t_zu, q_zu, U_blk, &
	95	& Cdn, Chn, Cen, &
	96	& Qsw, rad_lw, slp, pdT_cs, & ! optionals for cool-skin (and warm-layer)
[11816]	97	& pdT_wl, pHz_wl ) ! optionals for warm-layer only
[11329]	98	!!----------------------------------------------------------------------
[11615]	99	!! * ROUTINE turb_ecmwf *
[6723]	100	!!
	101	!! ** Purpose : Computes turbulent transfert coefficients of surface
[11615]	102	!! fluxes according to IFS doc. (cycle 45r1)
[6723]	103	!! If relevant (zt /= zu), adjust temperature and humidity from height zt to zu
[11329]	104	!! Returns the effective bulk wind speed at zu to be used in the bulk formulas
[6723]	105	!!
[11111]	106	!! Applies the cool-skin warm-layer correction of the SST to T_s
	107	!! if the net shortwave flux at the surface (Qsw), the downwelling longwave
	108	!! radiative fluxes at the surface (rad_lw), and the sea-leve pressure (slp)
	109	!! are provided as (optional) arguments!
[6723]	110	!!
	111	!! INPUT :
	112	!! -------
[11772]	113	!! * kt : current time step (starts at 1)
[6723]	114	!! * zt : height for temperature and spec. hum. of air [m]
[11291]	115	!! * zu : height for wind speed (usually 10m) [m]
[6723]	116	!! * t_zt : potential air temperature at zt [K]
	117	!! * q_zt : specific humidity of air at zt [kg/kg]
[11615]	118	!! * U_zu : scalar wind speed at zu [m/s]
	119	!! * l_use_cs : use the cool-skin parameterization
	120	!! * l_use_wl : use the warm-layer parameterization
[6723]	121	!!
[11111]	122	!! INPUT/OUTPUT:
	123	!! -------------
[11266]	124	!! * T_s : always "bulk SST" as input [K]
	125	!! -> unchanged "bulk SST" as output if CSWL not used [K]
	126	!! -> skin temperature as output if CSWL used [K]
	127	!!
[11111]	128	!! * q_s : SSQ aka saturation specific humidity at temp. T_s [kg/kg]
[11772]	129	!! -> doesn't need to be given a value if skin temp computed (in case l_use_cs=True or l_use_wl=True)
	130	!! -> MUST be given the correct value if not computing skint temp. (in case l_use_cs=False or l_use_wl=False)
[6723]	131	!!
[11619]	132	!! OPTIONAL INPUT:
[11111]	133	!! ---------------
	134	!! * Qsw : net solar flux (after albedo) at the surface (>0) [W/m^2]
	135	!! * rad_lw : downwelling longwave radiation at the surface (>0) [W/m^2]
	136	!! * slp : sea-level pressure [Pa]
[11772]	137	!!
	138	!! OPTIONAL OUTPUT:
	139	!! ----------------
[11615]	140	!! * pdT_cs : SST increment "dT" for cool-skin correction [K]
	141	!! * pdT_wl : SST increment "dT" for warm-layer correction [K]
[11772]	142	!! * pHz_wl : thickness of warm-layer [m]
[11111]	143	!!
[6723]	144	!! OUTPUT :
	145	!! --------
	146	!! * Cd : drag coefficient
	147	!! * Ch : sensible heat coefficient
	148	!! * Ce : evaporation coefficient
	149	!! * t_zu : pot. air temperature adjusted at wind height zu [K]
	150	!! * q_zu : specific humidity of air // [kg/kg]
[11291]	151	!! * U_blk : bulk wind speed at zu [m/s]
[6723]	152	!!
	153	!!
[11215]	154	!! ** Author: L. Brodeau, June 2019 / AeroBulk (https://github.com/brodeau/aerobulk/)
[6723]	155	!!----------------------------------------------------------------------------------
[11772]	156	INTEGER, INTENT(in ) :: kt ! current time step
[6723]	157	REAL(wp), INTENT(in ) :: zt ! height for t_zt and q_zt [m]
	158	REAL(wp), INTENT(in ) :: zu ! height for U_zu [m]
[11111]	159	REAL(wp), INTENT(inout), DIMENSION(jpi,jpj) :: T_s ! sea surface temperature [Kelvin]
[6723]	160	REAL(wp), INTENT(in ), DIMENSION(jpi,jpj) :: t_zt ! potential air temperature [Kelvin]
[11111]	161	REAL(wp), INTENT(inout), DIMENSION(jpi,jpj) :: q_s ! sea surface specific humidity [kg/kg]
	162	REAL(wp), INTENT(in ), DIMENSION(jpi,jpj) :: q_zt ! specific air humidity at zt [kg/kg]
[6723]	163	REAL(wp), INTENT(in ), DIMENSION(jpi,jpj) :: U_zu ! relative wind module at zu [m/s]
[11615]	164	LOGICAL , INTENT(in ) :: l_use_cs ! use the cool-skin parameterization
	165	LOGICAL , INTENT(in ) :: l_use_wl ! use the warm-layer parameterization
[6723]	166	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: Cd ! transfer coefficient for momentum (tau)
	167	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: Ch ! transfer coefficient for sensible heat (Q_sens)
	168	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: Ce ! transfert coefficient for evaporation (Q_lat)
	169	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: t_zu ! pot. air temp. adjusted at zu [K]
	170	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: q_zu ! spec. humidity adjusted at zu [kg/kg]
[11291]	171	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: U_blk ! bulk wind speed at zu [m/s]
[9019]	172	REAL(wp), INTENT( out), DIMENSION(jpi,jpj) :: Cdn, Chn, Cen ! neutral transfer coefficients
[6723]	173	!
[11111]	174	REAL(wp), INTENT(in ), OPTIONAL, DIMENSION(jpi,jpj) :: Qsw ! [W/m^2]
	175	REAL(wp), INTENT(in ), OPTIONAL, DIMENSION(jpi,jpj) :: rad_lw ! [W/m^2]
	176	REAL(wp), INTENT(in ), OPTIONAL, DIMENSION(jpi,jpj) :: slp ! [Pa]
[11615]	177	REAL(wp), INTENT( out), OPTIONAL, DIMENSION(jpi,jpj) :: pdT_cs
	178	REAL(wp), INTENT( out), OPTIONAL, DIMENSION(jpi,jpj) :: pdT_wl ! [K]
[11772]	179	REAL(wp), INTENT( out), OPTIONAL, DIMENSION(jpi,jpj) :: pHz_wl ! [m]
[11615]	180	!
[6723]	181	INTEGER :: j_itt
[11111]	182	LOGICAL :: l_zt_equal_zu = .FALSE. ! if q and t are given at same height as U
[6723]	183	!
[11111]	184	REAL(wp), DIMENSION(jpi,jpj) :: &
	185	& u_star, t_star, q_star, &
[6723]	186	& dt_zu, dq_zu, &
	187	& znu_a, & !: Nu_air, Viscosity of air
	188	& Linv, & !: 1/L (inverse of Monin Obukhov length...
	189	& z0, z0t, z0q
[11111]	190	!
[11615]	191	REAL(wp), DIMENSION(:,:), ALLOCATABLE :: &
	192	& zsst, & ! to back up the initial bulk SST
	193	& pdTc, & ! SST increment "dT" for cool-skin correction [K]
	194	& pdTw ! SST increment "dT" for warm layer correction [K]
[11111]	195	!
[9125]	196	REAL(wp), DIMENSION(jpi,jpj) :: func_m, func_h
	197	REAL(wp), DIMENSION(jpi,jpj) :: ztmp0, ztmp1, ztmp2
[11615]	198	CHARACTER(len=40), PARAMETER :: crtnm = 'turb_ecmwf@sbcblk_algo_ecmwf.F90'
[6723]	199	!!----------------------------------------------------------------------------------
[11215]	200
[11772]	201	IF ( kt == nit000 ) CALL ECMWF_INIT(l_use_cs, l_use_wl)
	202
[6723]	203	l_zt_equal_zu = .FALSE.
[11266]	204	IF( ABS(zu - zt) < 0.01_wp ) l_zt_equal_zu = .TRUE. ! testing "zu == zt" is risky with double precision
[6723]	205
[11615]	206	!! Initializations for cool skin and warm layer:
[11816]	207	IF ( l_use_cs .AND. (.NOT.(PRESENT(Qsw) .AND. PRESENT(rad_lw) .AND. PRESENT(slp))) ) &
	208	& CALL ctl_stop( '['//TRIM(crtnm)//'] => ' , 'you need to provide Qsw, rad_lw & slp to use cool-skin param!' )
[6723]	209
[11816]	210	IF ( l_use_wl .AND. (.NOT.(PRESENT(Qsw) .AND. PRESENT(rad_lw) .AND. PRESENT(slp))) ) &
	211	& CALL ctl_stop( '['//TRIM(crtnm)//'] => ' , 'you need to provide Qsw, rad_lw & slp to use warm-layer param!' )
[11615]	212
	213	IF ( l_use_cs .OR. l_use_wl ) THEN
	214	ALLOCATE ( zsst(jpi,jpj) )
	215	zsst = T_s ! backing up the bulk SST
	216	IF( l_use_cs ) T_s = T_s - 0.25_wp ! First guess of correction
[11785]	217	q_s = rdct_qsat_salt*q_sat(MAX(T_s, 200._wp), slp) ! First guess of q_s
[11615]	218	END IF
	219
	220
	221	! Identical first gess as in COARE, with IFS parameter values though...
	222	!
[6723]	223	!! First guess of temperature and humidity at height zu:
[11215]	224	t_zu = MAX( t_zt , 180._wp ) ! who knows what's given on masked-continental regions...
	225	q_zu = MAX( q_zt , 1.e-6_wp ) ! "
[6723]	226
	227	!! Pot. temp. difference (and we don't want it to be 0!)
[11111]	228	dt_zu = t_zu - T_s ; dt_zu = SIGN( MAX(ABS(dt_zu),1.E-6_wp), dt_zu )
	229	dq_zu = q_zu - q_s ; dq_zu = SIGN( MAX(ABS(dq_zu),1.E-9_wp), dq_zu )
[6723]	230
[11215]	231	znu_a = visc_air(t_zu) ! Air viscosity (m^2/s) at zt given from temperature in (K)
[6723]	232
[11291]	233	U_blk = SQRT(U_zuU_zu + 0.5_wp0.5_wp) ! initial guess for wind gustiness contribution
[6723]	234
[11291]	235	ztmp0 = LOG( zu*10000._wp) ! optimization: 10000. == 1/z0 (with z0 first guess == 0.0001)
	236	ztmp1 = LOG(10._wp*10000._wp) ! " " "
[11111]	237	u_star = 0.035_wpU_blkztmp1/ztmp0 ! (u* = 0.035*Un10)
[6723]	238
[11111]	239	z0 = charn0u_staru_star/grav + 0.11_wp*znu_a/u_star
[11785]	240	z0 = MIN( MAX(ABS(z0), 1.E-9) , 1._wp ) ! (prevents FPE from stupid values from masked region later on)
	241
[11111]	242	z0t = 1._wp / ( 0.1_wp*EXP(vkarmn/(0.00115/(vkarmn/ztmp1))) )
[11785]	243	z0t = MIN( MAX(ABS(z0t), 1.E-9) , 1._wp ) ! (prevents FPE from stupid values from masked region later on)
[6723]	244
[11615]	245	Cd = (vkarmn/ztmp0)**2 ! first guess of Cd
[6723]	246
[11111]	247	ztmp0 = vkarmn*vkarmn/LOG(zt/z0t)/Cd
[6723]	248
[11209]	249	ztmp2 = Ri_bulk( zu, T_s, t_zu, q_s, q_zu, U_blk ) ! Bulk Richardson Number (BRN)
[6723]	250
[11209]	251	!! First estimate of zeta_u, depending on the stability, ie sign of BRN (ztmp2):
[11111]	252	ztmp1 = 0.5 + SIGN( 0.5_wp , ztmp2 )
[6723]	253	func_m = ztmp0*ztmp2 ! temporary array !!
[11215]	254	func_h = (1._wp-ztmp1) * (func_m/(1._wp+ztmp2/(-zu/(zi00.004_wpBeta0**3)))) & ! BRN < 0 ! temporary array !!! func_h == zeta_u
	255	& + ztmp1 * (func_m(1._wp + 27._wp/9._wpztmp2/func_m)) ! BRN > 0
[11111]	256	!#LB: should make sure that the "func_m" of "27./9.ztmp2/func_m" is "ztmp0ztmp2" and not "ztmp0==vkarmn*vkarmn/LOG(zt/z0t)/Cd" !
[6723]	257
	258	!! First guess M-O stability dependent scaling params.(u,t,q*) to estimate z0 and z/L
[11111]	259	ztmp0 = vkarmn/(LOG(zu/z0t) - psi_h_ecmwf(func_h))
[6723]	260
[11785]	261	u_star = MAX ( U_blk*vkarmn/(LOG(zu) - LOG(z0) - psi_m_ecmwf(func_h)) , 1.E-9 ) ! (MAX => prevents FPE from stupid values from masked region later on)
[6723]	262	t_star = dt_zu*ztmp0
	263	q_star = dq_zu*ztmp0
	264
[11266]	265	! What needs to be done if zt /= zu:
[6723]	266	IF( .NOT. l_zt_equal_zu ) THEN
	267	!! First update of values at zu (or zt for wind)
	268	ztmp0 = psi_h_ecmwf(func_h) - psi_h_ecmwf(ztfunc_h/zu) ! ztfunc_h/zu == zeta_t
[11111]	269	ztmp1 = LOG(zt/zu) + ztmp0
[6723]	270	t_zu = t_zt - t_star/vkarmn*ztmp1
	271	q_zu = q_zt - q_star/vkarmn*ztmp1
[11111]	272	q_zu = (0.5_wp + SIGN(0.5_wp,q_zu))*q_zu !Makes it impossible to have negative humidity :
[6723]	273	!
[11111]	274	dt_zu = t_zu - T_s ; dt_zu = SIGN( MAX(ABS(dt_zu),1.E-6_wp), dt_zu )
	275	dq_zu = q_zu - q_s ; dq_zu = SIGN( MAX(ABS(dq_zu),1.E-9_wp), dq_zu )
	276	END IF
[6723]	277
	278
	279	!! => that was same first guess as in COARE...
	280
	281
	282	!! First guess of inverse of Monin-Obukov length (1/L) :
[11209]	283	Linv = One_on_L( t_zu, q_zu, u_star, t_star, q_star )
[6723]	284
	285	!! Functions such as u* = U_blk*vkarmn/func_m
[11111]	286	ztmp0 = zu*Linv
	287	func_m = LOG(zu) - LOG(z0) - psi_m_ecmwf(ztmp0) + psi_m_ecmwf( z0*Linv)
	288	func_h = LOG(zu) - LOG(z0t) - psi_h_ecmwf(ztmp0) + psi_h_ecmwf(z0t*Linv)
[6723]	289
	290	!! ITERATION BLOCK
	291	DO j_itt = 1, nb_itt
	292
	293	!! Bulk Richardson Number at z=zu (Eq. 3.25)
[11209]	294	ztmp0 = Ri_bulk( zu, T_s, t_zu, q_s, q_zu, U_blk ) ! Bulk Richardson Number (BRN)
[6723]	295
	296	!! New estimate of the inverse of the Monin-Obukhon length (Linv == zeta/zu) :
[11111]	297	Linv = ztmp0func_mfunc_m/func_h / zu ! From Eq. 3.23, Chap.3.2.3, IFS doc - Cy40r1
	298	!! Note: it is slightly different that the L we would get with the usual
	299	Linv = SIGN( MIN(ABS(Linv),200._wp), Linv ) ! (prevent FPE from stupid values from masked region later on...) !#LOLO
[6723]	300
	301	!! Update func_m with new Linv:
[11111]	302	func_m = LOG(zu) -LOG(z0) - psi_m_ecmwf(zuLinv) + psi_m_ecmwf(z0Linv) ! LB: should be "zu+z0" rather than "zu" alone, but z0 is tiny wrt zu!
[6723]	303
	304	!! Need to update roughness lengthes:
	305	u_star = U_blk*vkarmn/func_m
	306	ztmp2 = u_star*u_star
	307	ztmp1 = znu_a/u_star
[11111]	308	z0 = MIN( ABS( alpha_Mztmp1 + charn0ztmp2/grav ) , 0.001_wp)
	309	z0t = MIN( ABS( alpha_H*ztmp1 ) , 0.001_wp) ! eq.3.26, Chap.3, p.34, IFS doc - Cy31r1
	310	z0q = MIN( ABS( alpha_Q*ztmp1 ) , 0.001_wp)
[11209]	311
[11615]	312	!! Update wind at zu with convection-related wind gustiness in unstable conditions (Chap. 3.2, IFS doc - Cy40r1, Eq.3.17 and Eq.3.18 + Eq.3.8)
	313	ztmp2 = Beta0Beta0ztmp2(MAX(-zi0Linv/vkarmn,0._wp))**(2._wp/3._wp) ! square of wind gustiness contribution (combining Eq. 3.8 and 3.18, hap.3, IFS doc - Cy31r1)
	314	!! ! Only true when unstable (L<0) => when ztmp0 < 0 => explains "-" before zi0
	315	U_blk = MAX(SQRT(U_zu*U_zu + ztmp2), 0.2_wp) ! include gustiness in bulk wind speed
[6723]	316	! => 0.2 prevents U_blk to be 0 in stable case when U_zu=0.
	317
	318
	319	!! Need to update "theta" and "q" at zu in case they are given at different heights
	320	!! as well the air-sea differences:
	321	IF( .NOT. l_zt_equal_zu ) THEN
	322	!! Arrays func_m and func_h are free for a while so using them as temporary arrays...
[11111]	323	func_h = psi_h_ecmwf(zu*Linv) ! temporary array !!!
	324	func_m = psi_h_ecmwf(zt*Linv) ! temporary array !!!
[6723]	325
	326	ztmp2 = psi_h_ecmwf(z0t*Linv)
	327	ztmp0 = func_h - ztmp2
[11111]	328	ztmp1 = vkarmn/(LOG(zu) - LOG(z0t) - ztmp0)
[6723]	329	t_star = dt_zu*ztmp1
	330	ztmp2 = ztmp0 - func_m + ztmp2
	331	ztmp1 = LOG(zt/zu) + ztmp2
	332	t_zu = t_zt - t_star/vkarmn*ztmp1
	333
	334	ztmp2 = psi_h_ecmwf(z0q*Linv)
	335	ztmp0 = func_h - ztmp2
[11111]	336	ztmp1 = vkarmn/(LOG(zu) - LOG(z0q) - ztmp0)
[6723]	337	q_star = dq_zu*ztmp1
	338	ztmp2 = ztmp0 - func_m + ztmp2
[11111]	339	ztmp1 = LOG(zt/zu) + ztmp2
[6723]	340	q_zu = q_zt - q_star/vkarmn*ztmp1
[11111]	341	END IF
[6723]	342
[11111]	343	!! Updating because of updated z0 and z0t and new Linv...
	344	ztmp0 = zu*Linv
	345	func_m = log(zu) - LOG(z0 ) - psi_m_ecmwf(ztmp0) + psi_m_ecmwf(z0 *Linv)
	346	func_h = log(zu) - LOG(z0t) - psi_h_ecmwf(ztmp0) + psi_h_ecmwf(z0t*Linv)
[9019]	347
[11615]	348
	349	IF( l_use_cs ) THEN
	350	!! Cool-skin contribution
	351
[11772]	352	CALL UPDATE_QNSOL_TAU( zu, T_s, q_s, t_zu, q_zu, u_star, t_star, q_star, U_zu, U_blk, slp, rad_lw, &
[11615]	353	& ztmp1, ztmp0, Qlat=ztmp2) ! Qnsol -> ztmp1 / Tau -> ztmp0
	354
[11772]	355	CALL CS_ECMWF( Qsw, ztmp1, u_star, zsst ) ! Qnsol -> ztmp1
[11615]	356
[11772]	357	T_s(:,:) = zsst(:,:) + dT_cs(:,:)*tmask(:,:,1)
	358	IF( l_use_wl ) T_s(:,:) = T_s(:,:) + dT_wl(:,:)*tmask(:,:,1)
[11615]	359	q_s(:,:) = rdct_qsat_salt*q_sat(MAX(T_s(:,:), 200._wp), slp(:,:))
	360
[6723]	361	END IF
	362
[11615]	363	IF( l_use_wl ) THEN
	364	!! Warm-layer contribution
[11772]	365	CALL UPDATE_QNSOL_TAU( zu, T_s, q_s, t_zu, q_zu, u_star, t_star, q_star, U_zu, U_blk, slp, rad_lw, &
[11615]	366	& ztmp1, ztmp2) ! Qnsol -> ztmp1 / Tau -> ztmp2
[11772]	367	CALL WL_ECMWF( Qsw, ztmp1, u_star, zsst )
[11615]	368	!! Updating T_s and q_s !!!
[11772]	369	T_s(:,:) = zsst(:,:) + dT_wl(:,:)*tmask(:,:,1)
	370	IF( l_use_cs ) T_s(:,:) = T_s(:,:) + dT_cs(:,:)*tmask(:,:,1)
[11615]	371	q_s(:,:) = rdct_qsat_salt*q_sat(MAX(T_s(:,:), 200._wp), slp(:,:))
	372	END IF
	373
	374	IF( l_use_cs .OR. l_use_wl .OR. (.NOT. l_zt_equal_zu) ) THEN
[11111]	375	dt_zu = t_zu - T_s ; dt_zu = SIGN( MAX(ABS(dt_zu),1.E-6_wp), dt_zu )
	376	dq_zu = q_zu - q_s ; dq_zu = SIGN( MAX(ABS(dq_zu),1.E-9_wp), dq_zu )
	377	END IF
[6723]	378
[11111]	379	END DO !DO j_itt = 1, nb_itt
[6723]	380
	381	Cd = vkarmnvkarmn/(func_mfunc_m)
	382	Ch = vkarmnvkarmn/(func_mfunc_h)
[11111]	383	ztmp2 = log(zu/z0q) - psi_h_ecmwf(zuLinv) + psi_h_ecmwf(z0qLinv) ! func_q
	384	Ce = vkarmnvkarmn/(func_mztmp2)
[6723]	385
[11111]	386	Cdn = vkarmnvkarmn / (log(zu/z0 )log(zu/z0 ))
	387	Chn = vkarmnvkarmn / (log(zu/z0t)log(zu/z0t))
	388	Cen = vkarmnvkarmn / (log(zu/z0q)log(zu/z0q))
[9019]	389
[11772]	390	IF ( l_use_cs .AND. PRESENT(pdT_cs) ) pdT_cs = dT_cs
	391	IF ( l_use_wl .AND. PRESENT(pdT_wl) ) pdT_wl = dT_wl
	392	IF ( l_use_wl .AND. PRESENT(pHz_wl) ) pHz_wl = Hz_wl
[6723]	393
[11615]	394	IF ( l_use_cs .OR. l_use_wl ) DEALLOCATE ( zsst )
[6723]	395
[11615]	396	END SUBROUTINE turb_ecmwf
	397
	398
[6723]	399	FUNCTION psi_m_ecmwf( pzeta )
	400	!!----------------------------------------------------------------------------------
	401	!! Universal profile stability function for momentum
	402	!! ECMWF / as in IFS cy31r1 documentation, available online
	403	!! at ecmwf.int
	404	!!
	405	!! pzeta : stability paramenter, z/L where z is altitude measurement
	406	!! and L is M-O length
	407	!!
[11215]	408	!! ** Author: L. Brodeau, June 2016 / AeroBulk (https://github.com/brodeau/aerobulk/)
[6723]	409	!!----------------------------------------------------------------------------------
	410	REAL(wp), DIMENSION(jpi,jpj) :: psi_m_ecmwf
	411	REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pzeta
	412	!
	413	INTEGER :: ji, jj ! dummy loop indices
	414	REAL(wp) :: zzeta, zx, ztmp, psi_unst, psi_stab, stab
	415	!!----------------------------------------------------------------------------------
	416	DO jj = 1, jpj
	417	DO ji = 1, jpi
	418	!
[11111]	419	zzeta = MIN( pzeta(ji,jj) , 5._wp ) !! Very stable conditions (L positif and big!):
[6723]	420	!
	421	! Unstable (Paulson 1970):
	422	! eq.3.20, Chap.3, p.33, IFS doc - Cy31r1
[11111]	423	zx = SQRT(ABS(1._wp - 16._wp*zzeta))
	424	ztmp = 1._wp + SQRT(zx)
[6723]	425	ztmp = ztmp*ztmp
[11111]	426	psi_unst = LOG( 0.125_wpztmp(1._wp + zx) ) &
	427	& -2._wpATAN( SQRT(zx) ) + 0.5_wprpi
[6723]	428	!
	429	! Unstable:
	430	! eq.3.22, Chap.3, p.33, IFS doc - Cy31r1
[11111]	431	psi_stab = -2._wp/3._wp(zzeta - 5._wp/0.35_wp)EXP(-0.35_wp*zzeta) &
	432	& - zzeta - 2._wp/3._wp*5._wp/0.35_wp
[6723]	433	!
	434	! Combining:
[11111]	435	stab = 0.5_wp + SIGN(0.5_wp, zzeta) ! zzeta > 0 => stab = 1
[6723]	436	!
[11111]	437	psi_m_ecmwf(ji,jj) = (1._wp - stab) * psi_unst & ! (zzeta < 0) Unstable
	438	& + stab * psi_stab ! (zzeta > 0) Stable
[6723]	439	!
	440	END DO
	441	END DO
	442	END FUNCTION psi_m_ecmwf
	443
[11111]	444
[6723]	445	FUNCTION psi_h_ecmwf( pzeta )
	446	!!----------------------------------------------------------------------------------
	447	!! Universal profile stability function for temperature and humidity
	448	!! ECMWF / as in IFS cy31r1 documentation, available online
	449	!! at ecmwf.int
	450	!!
	451	!! pzeta : stability paramenter, z/L where z is altitude measurement
	452	!! and L is M-O length
	453	!!
[11215]	454	!! ** Author: L. Brodeau, June 2016 / AeroBulk (https://github.com/brodeau/aerobulk/)
[6723]	455	!!----------------------------------------------------------------------------------
	456	REAL(wp), DIMENSION(jpi,jpj) :: psi_h_ecmwf
	457	REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pzeta
	458	!
	459	INTEGER :: ji, jj ! dummy loop indices
	460	REAL(wp) :: zzeta, zx, psi_unst, psi_stab, stab
	461	!!----------------------------------------------------------------------------------
	462	!
	463	DO jj = 1, jpj
	464	DO ji = 1, jpi
	465	!
[11111]	466	zzeta = MIN(pzeta(ji,jj) , 5._wp) ! Very stable conditions (L positif and big!):
[6723]	467	!
[11111]	468	zx = ABS(1._wp - 16._wpzzeta).25 ! this is actually (1/phi_m)*2 !!!
[6723]	469	! ! eq.3.19, Chap.3, p.33, IFS doc - Cy31r1
	470	! Unstable (Paulson 1970) :
[11111]	471	psi_unst = 2._wpLOG(0.5_wp(1._wp + zx*zx)) ! eq.3.20, Chap.3, p.33, IFS doc - Cy31r1
[6723]	472	!
	473	! Stable:
[11111]	474	psi_stab = -2._wp/3._wp(zzeta - 5._wp/0.35_wp)EXP(-0.35_wp*zzeta) & ! eq.3.22, Chap.3, p.33, IFS doc - Cy31r1
	475	& - ABS(1._wp + 2._wp/3._wpzzeta)1.5_wp - 2._wp/3._wp5._wp/0.35_wp + 1._wp
[6723]	476	! LB: added ABS() to avoid NaN values when unstable, which contaminates the unstable solution...
	477	!
[11111]	478	stab = 0.5_wp + SIGN(0.5_wp, zzeta) ! zzeta > 0 => stab = 1
[6723]	479	!
	480	!
[11111]	481	psi_h_ecmwf(ji,jj) = (1._wp - stab) * psi_unst & ! (zzeta < 0) Unstable
	482	& + stab * psi_stab ! (zzeta > 0) Stable
[6723]	483	!
	484	END DO
	485	END DO
	486	END FUNCTION psi_h_ecmwf
	487
	488
	489	!!======================================================================
	490	END MODULE sbcblk_algo_ecmwf

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