source: LMDZ6/branches/blowing_snow/libf/phylmd/atke_exchange_coeff_mod.F90 @ 5018

Last change on this file since 5018 was 4481, checked in by evignon, 19 months ago

quelques petites modifs pour le prochain atelier tke (lundi 03/04/2023)

File size: 7.6 KB
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1module atke_exchange_coeff_mod
2
3implicit none
4
5contains
6
7subroutine atke_compute_km_kh(ngrid,nlay, &
8                        wind_u,wind_v,temp,play,pinterf, &
9                        tke,Km_out,Kh_out)
10
11!========================================================================
12! Routine that computes turbulent Km / Kh coefficients with a
13! 1.5 order closure scheme (TKE) with or without stationarity assumption
14!
15! This parameterization has been constructed in the framework of a
16! collective and collaborative workshop,
17! the so-called 'Atelier TKE (ATKE)' with
18! K. Arjdal, L. Raillard, C. Dehondt, P. Tiengou, A. Spiga, F. Cheruy, T Dubos,
19! M. Coulon-Decorzens, S. Fromang, G. Riviere, A. Sima, F. Hourdin, E. Vignon
20!
21! Main assumptions of the model :
22! (1) dry atmosphere
23! (2) horizontal homogeneity (Dx=Dy=0.)
24!=======================================================================
25
26
27
28USE atke_turbulence_ini_mod, ONLY : iflag_atke, kappa, l0, ric, cinf, rpi, rcpd
29USE atke_turbulence_ini_mod, ONLY : cepsilon, pr_slope, pr_asym, pr_neut, rg, rd
30USE atke_turbulence_ini_mod, ONLY : viscom, viscoh
31
32implicit none
33
34
35! Declarations:
36!=============
37
38INTEGER, INTENT(IN) :: ngrid ! number of horizontal index (flat grid)
39INTEGER, INTENT(IN) :: nlay ! number of vertical index 
40
41REAL, DIMENSION(ngrid,nlay), INTENT(IN)       :: wind_u   ! zonal velocity (m/s)
42REAL, DIMENSION(ngrid,nlay), INTENT(IN)       :: wind_v   ! meridional velocity (m/s)
43REAL, DIMENSION(ngrid,nlay), INTENT(IN)       :: temp   ! temperature (K)
44REAL, DIMENSION(ngrid,nlay), INTENT(IN)       :: play   ! pressure (Pa)
45REAL, DIMENSION(ngrid,nlay+1), INTENT(IN)     :: pinterf   ! pressure at interfaces(Pa)
46
47
48REAL, DIMENSION(ngrid,nlay+1), INTENT(INOUT)  :: tke  ! turbulent kinetic energy at interface between layers
49
50REAL, DIMENSION(ngrid,nlay), INTENT(OUT)      :: Km_out   ! output: Exchange coefficient for momentum at interface between layers
51REAL, DIMENSION(ngrid,nlay), INTENT(OUT)      :: Kh_out   ! output: Exchange coefficient for heat flux at interface between layers
52
53! Local variables
54REAL, DIMENSION(ngrid,nlay+1) :: Km          ! Exchange coefficient for momentum at interface between layers
55REAL, DIMENSION(ngrid,nlay+1) :: Kh          ! Exchange coefficient for heat flux at interface between layers
56REAL, DIMENSION(ngrid,nlay)   :: theta       ! Potential temperature
57REAL, DIMENSION(ngrid,nlay+1) :: l_exchange  ! Length of exchange (at interface)
58REAL, DIMENSION(ngrid,nlay+1) :: z_interf    ! Altitude at the interface
59REAL, DIMENSION(ngrid,nlay)   :: z_lay       ! Altitude of layers
60REAL, DIMENSION(ngrid,nlay)   :: dz_interf   ! distance between two consecutive interfaces
61REAL, DIMENSION(ngrid,nlay)   :: dz_lay      ! distance between two layer middles (NB: first and last are half layers)
62REAL, DIMENSION(ngrid,nlay+1) :: Ri          ! Richardson's number (at interface)
63REAL, DIMENSION(ngrid,nlay+1) :: Prandtl     ! Turbulent Prandtl's number (at interface)
64REAL, DIMENSION(ngrid,nlay+1) :: Sm          ! Stability function for momentum (at interface)
65REAL, DIMENSION(ngrid,nlay+1) :: Sh          ! Stability function for heat (at interface)
66
67INTEGER :: igrid,ilay ! horizontal,vertical index (flat grid)
68REAL    :: cn,Ri0,Ri1    ! parameter for Sm stability function and Prandlt
69REAL    :: preff      ! reference pressure for potential temperature calculations
70REAL    :: thetam     ! mean potential temperature at interface
71
72
73! Initializations:
74!================
75
76DO igrid=1,ngrid
77    dz_interf(igrid,1) = 0.0
78    z_interf(igrid,1) = 0.0
79END DO
80
81! Calculation of potential temperature: (if vapor -> todo virtual potential temperature)
82!=====================================
83
84preff=100000.
85! The result should not depend on the choice of preff
86DO ilay=1,nlay
87     DO igrid = 1, ngrid
88        theta(igrid,ilay)=temp(igrid,ilay)*(preff/play(igrid,ilay))**(rd/rcpd)
89     END DO
90END DO
91
92
93
94! Calculation of altitude of layers' middle and bottom interfaces:
95!=================================================================
96
97DO ilay=2,nlay+1
98    DO igrid=1,ngrid
99        dz_interf(igrid,ilay-1) = rd*temp(igrid,ilay-1)/rg/play(igrid,ilay-1)*(pinterf(igrid,ilay-1)-pinterf(igrid,ilay))
100        z_interf(igrid,ilay) = z_interf(igrid,ilay-1) + dz_interf(igrid,ilay-1)
101    ENDDO
102ENDDO
103
104DO ilay=1,nlay
105   DO igrid=1,ngrid
106      z_lay(igrid,ilay)=0.5*(z_interf(igrid, ilay+1) + z_interf(igrid, ilay))
107   ENDDO
108ENDDO
109
110
111! Computing the mixing length:
112! so far, we have neglected the effect of local stratification
113!==============================================================
114
115
116DO ilay=2,nlay+1
117    DO igrid=1,ngrid
118        l_exchange(igrid,ilay) = kappa*l0*z_interf(igrid,ilay) / (kappa*z_interf(igrid,ilay) + l0)
119    ENDDO
120ENDDO
121
122! Computes the gradient Richardson's number and stability functions:
123!===================================================================
124
125! calculation of cn = Sm value at Ri=0
126! direct dependance on cepsilon to guarantee Fm=1 (first-order like stability function) at Ri=0
127cn=(1./sqrt(cepsilon))**(2/3)
128! calculation of Ri0 such that continuity in slope of Sm at Ri=0
129Ri0=2./rpi*(cinf - cn)*ric/cn
130! calculation of Ri1 to guarantee continuity in slope of Prandlt number at Ri=0
131Ri1 = -2./rpi * (pr_asym - pr_neut) / pr_slope
132
133
134DO ilay=2,nlay
135    DO igrid=1,ngrid
136        dz_lay(igrid,ilay)=z_lay(igrid,ilay)-z_lay(igrid,ilay-1)
137        thetam=0.5*(theta(igrid,ilay) + theta(igrid,ilay-1))
138        Ri(igrid,ilay) = rg * (theta(igrid,ilay) - theta(igrid,ilay-1))/thetam / dz_lay(igrid,ilay) / &
139        MAX(((wind_u(igrid,ilay) - wind_u(igrid,ilay-1)) / dz_lay(igrid,ilay))**2 + &
140        ((wind_v(igrid,ilay) - wind_v(igrid,ilay-1)) / dz_lay(igrid,ilay))**2,1E-10)
141       
142        IF (Ri(igrid,ilay) < 0.) THEN ! unstable cases
143            Sm(igrid,ilay) = 2./rpi * (cinf-cn) * atan(-Ri(igrid,ilay)/Ri0) + cn
144            Prandtl(igrid,ilay) = -2./rpi * (pr_asym - pr_neut) * atan(Ri(igrid,ilay)/Ri1) + pr_neut
145        ELSE ! stable cases
146            Sm(igrid,ilay) = max(0.,cn*(1.-Ri(igrid,ilay)/Ric))
147            Prandtl(igrid,ilay) = pr_neut + Ri(igrid,ilay) * pr_slope
148            IF (Ri(igrid,ilay) .GE. Prandtl(igrid,ilay)) THEN
149               call abort_physic("atke_compute_km_kh", &
150               'Ri>=Pr in stable conditions -> violates energy conservation principles, change pr_neut or slope', 1)
151            ENDIF
152        END IF
153       
154        Sh(igrid,ilay) = Sm(igrid,ilay) / Prandtl(igrid,ilay)
155
156    ENDDO
157ENDDO
158
159! Computing the TKE:
160!===================
161IF (iflag_atke == 0) THEN
162
163! stationary solution neglecting the vertical transport of TKE by turbulence
164    DO ilay=2,nlay
165        DO igrid=1,ngrid
166            tke(igrid,ilay) = cepsilon * l_exchange(igrid,ilay)**2 * Sm(igrid,ilay) * &
167            (((wind_u(igrid,ilay) - wind_u(igrid,ilay-1)) / dz_lay(igrid,ilay))**2 + &
168            ((wind_v(igrid,ilay) - wind_v(igrid,ilay-1)) / dz_lay(igrid,ilay))**2 ) * &
169            (1. - Ri(igrid,ilay) / Prandtl(igrid,ilay))
170        ENDDO
171    ENDDO
172
173ELSE ! TO DO
174   
175   call abort_physic("atke_compute_km_kh", &
176        'traitement non-stationnaire de la tke pas encore prevu', 1)
177
178END IF
179
180
181! Computing eddy diffusivity coefficients:
182!========================================
183DO ilay=2,nlay ! TODO: also calculate for nlay+1 ?
184    DO igrid=1,ngrid
185        ! we add the molecular viscosity to Km,h
186        Km(igrid,ilay) = viscom + l_exchange(igrid,ilay) * Sm(igrid,ilay) * tke(igrid,ilay)**0.5
187        Kh(igrid,ilay) = viscoh + l_exchange(igrid,ilay) * Sh(igrid,ilay) * tke(igrid,ilay)**0.5
188    END DO
189END DO
190
191! for output:
192!===========
193Km_out(1:ngrid,2:nlay)=Km(1:ngrid,2:nlay)
194Kh_out(1:ngrid,2:nlay)=Kh(1:ngrid,2:nlay)
195
196end subroutine atke_compute_km_kh
197
198
199end module atke_exchange_coeff_mod
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