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LES modeling of precipitation in Boundary Layer Clouds and parameterisation for General Circulation Model O. Geoffroy J.L. Brenguier CNRM/GMEI/MNPCA
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Why studying precipitation in BLSC (Boundary Layer Stratocumulus Clouds ) ? Parameterization of drizzle formation and precipitation in BLSC is a key step in numerical modeling of the aerosol impact on climate Why studying Stratocumulus clouds ? - Radiative properties : ALB strato ~10*ALB sea - Large occurrence : ~ 20-30 % of the ocean’s surface. Negative global radiative forcing Hydrological point of view : Precipitation flux in BLSC ~mm d -1 against ~mm h -1 in deep convection clouds BLSC are considered as non precipitating clouds Energetic point of view : 1mm d -1 ~ -30 W m -2 Significant impact on the energy balance of STBL and on their life cycle Aerosol impact on climate NaNa rvrv NcNc precipitations
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The problem of modeling precipitation formation in GCM Presently in GCM : parameterisation schemes of precipitation directly transposed from CRM bulk parameterization. Example : Problem - no physically based parameterisations - Numerical instability due to step function Are such parameterisations, with tuned coefficients, still valid to study the AIE? 2 nd solution A parameterisation of the precipitation flux averaged over an ensemble of cells is more relevant for the GCM resolution scale Underestimation of precipitation 1 st solution This bias is corrected by using tuning coefficients In Manton-Cotton parameterisation : rv crit =10 µm In GCM : rv crit reduced down to 5 µm. Problem : Inhomogeneity of microphysical variables. Formation of precipitation = non linear process local value have to be explicitely resolved LES resolution: ~100m horizontally, ~10 m vertically 3D view of LWC = 0.1 g kg -1 isocontour, from the side and above. LES domainCorresponding cloud in GCM grid point ~100m in BL ~100km Homogeneous cloud Cloud fraction F, (m -3 ) In GCM : variables are mean values over 10 to 100 km scales smoothing effect on local peak values.
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Super bulk parameterisation At the scale of an ensemble of cloud cells : quasi stationnary state Is it feasible to express the mean precipitation flux at cloud base as a function of macrophysical variables that characterise the cloud layer as a whole ? (Pawlowska & Brenguier, 2003) Pawlowska & Brenguier (2003, ACE-2): Comstock & al. (2004, EPIC) : Van Zanten & al. (2005, DYCOMS-II) : Which variables drive at the cloud system scale ? Adiabatic model : LWP = ½C w H 2 (kg m -2 s -1 or mm d -1 ) H (m) or (kg m -2 ) N (m -3 ) In GCMs, H (or LWP) and N can be predicted at the scale of the cloud system - The LWC sink term due to precipitation, averaged over numerous cloud cells, can then be expressed as a function of these two variabless : (kg m -3 s -1 )
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Objectives & Methodology Methodology: 3D LES simulations of BLSC fields with various H (LWP) and N values Objectives : - use LES to establish the relationship between, LWP and N, and empirically determine the coefficients. H or, N a = ? α = ? β = ? LES domainGCM grid point averaged LWP, N, and over the simulation domain 10 km
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LES microphysical scheme - Implementation in MESONH of a modified version of the Khairoutdinov & Kogan (2000) LES bulk microphysical scheme (available in MASDEV4_7 version). Specificities : - 2 moments -> predict N for studies of the aerosol impact -- specifically designed for BLC = low precipitating clouds - coefficients tuned using an explicit microphysical model as data source -> using realistic distributions. - LES scheme -> valid only for CRM. - Modifications : Cohard and Pinty (1998) activation scheme and add of droplet sedimentation process. Condensation & Evaporation : Langlois (1973) Autoconversion : K&K (2000) Accretion :K&K (2000) Sedimentation of drizzle : K&K (2000) Activation : Cohard et al (1998) Evaporation : K&K (2000) Aerosol : N CCN (m -3 ) (Constant parameter) + Vertical velocity : W N act (m -3 ) Cloud : q cloud (kg/kg) N cloud (m -3 ) Drizzle: q drizzle (kg/kg) N drizzle (m -3 ) Sedimentation of cloud droplets Stokes law + gamma Vapour: q vapour (kg/kg) Microphysical processes & microphysical variables.
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(H) : Stokes regime: Parameterisation of cloud droplets sedimentation Calculation of the cloud droplet sedimentation process requires an idealized droplet size distribution. Objective : Which distribution to select? With which parameter ? Generalized gamma law :Lognormal law : Methodology. By comparing with ACE-2 measured spectra (resolution = 100 m), find the idealized distribution which best represents the : - diameter of the 2 nd moment, - diameter of the 5 th moment, - effective diameter. The cloud sedimentation flux depends on the 2 nd and 5 th moments Radiatives flux in LW depends on the effective radius.
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Results for gamma law, α=3, υ=2 Number of spectra in % of max_pts 100 % 50 % 0 % Ø2Ø2 σ ØeØe ØeØe Ø5Ø5 - Generalized gamma law : best results for α=3, υ=2 - Lognormal law, similar results with σ g =1.2 ~ DYCOMS-II results (M.C. Van Zanten personnal communication). only spectra at cloud top
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Results for lognormal law, σ g =1.5 % of max_pts 100 % 50 % 0 % Ø2Ø2 σ ØeØe ØeØe Ø5Ø5 Lognormal law, with σ g =1.5, overestimate sedimentation flux of cloud droplets. only spectra at cloud top
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GCSS intercomparison exercise Case coordinator : A. Ackermann (2005) Case studied : 2 nd research flight (RF02) of DYCOMS-II experiment (Stevens et al., 2003) Domain : 6.4 km × 6.4 km × 1.5 km horizontal resolution : 50 m, vertical resolution : 5 m near the surface and the initial inversion at 795 m. fixed LW radiative fluxes, fixed surface fluxes, fixed cloud droplet concentration : Nc = 55 cm -3 2 simulations : - 1 without cloud droplet sedimentation. - 1 with cloud droplet sedimentation : lognormale law with σ g = 1.5 Microphysical schemes tested : - K&K scheme, - C2R2 scheme (= Berry and Reinhardt scheme (1974)). 4 simulations. K&K, sed ON / sed OFF C2R2, sed ON / sed OFF
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Results, LWP, precipitation flux Central half of the simulation ensemble Ensemble range Median value of the ensemble of models K&K, sed : ON K&K, sed : OFF NO DATA LWP (g m -2 ) = f(t) Precipitation flux at surface (mm d -1 ) = f(t) Precipitation flux at cloud base (mm d -1 ) = f(t) C2R2, sed ON C2R2, sed OFF 6H 3H 6H 3H6H observations - LWP a little too low - Underestimation of precipitation flux ~0.35 mm d -1 ~1.24 mm d -1
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Results,discussion Strong variability of N and F prec : Black : F prec > 5 mm d -1 Light grey : F prec < 1 mm d -1 N c (cm -3 ) Variation of N c along 1 cloud top leg Resolution : 1 km (Van Zanten et al, 20004) measures Nc < 55 cm -3 in heavily precipitating areas.
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Results, What about microphysics ? Observations Variations of N, geometrical diameter for cloud and for drizzle, along 1 cloud top leg, 1 cloud base leg. (Van Zanten personnal communication). Averaged profils on precipitating grid points after 2 hours of simulation : N drizzle, q drizzle, Øv drizzle, Øv cloud C2R2 K&K N drizzle (l -1 ) q drizzle (g kg -1 ) Ø v drizzle (µm) Ø v cloud (µm) Simulations - Underestimation of precipitation flux at the base for K&K scheme and C2R2 scheme. N c is too large in simulation? LWP is too low? - K&K scheme reproduce with good agreement microphysical variables. C2R2 scheme : large and few drops. N c (cm -3 ), N drizzle (l -1 )Øg cø, Øg drizzle (µm) Cloud Top leg Cloud base leg K&K C2R2
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Results, super bulk parameterization : averaged precipitation flux at cloud base (kg m -2 s -1 ) 7 simulations with different values of N : N a = 25, 50, 75, 100, 200, 400, 800 cm -3 -> different values of N Simulations of diurnal cycles -> variations of LWP Domain : 2,5 km * 2,5 km * 1220 m horizontal resolution : 50 m, vertical resolution : 10 m. = (LWP/N)
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Conclusion & Perspectives - Cloud droplet sedimentation : Best fit with α = 3, υ = 2 for generalized gamma law, σ g = 1,2 for lognormal law. - Validation of the microphysical scheme : GCSS intercomparison exercise The K&K scheme shows a good agreement with observations for microphysical variables Underestimation of the precipitation flux with respect to observations. Nc too large ? -> Simulations with N c prognostic Simulation of 2 ACE-2 case -> Simulations of a clear and a polluted case of the ACE-2 experiment and comparison with observations - Parameterisation of the precipitation flux for GCM : corroborates experimental results : is a function of LWP and N -> 3D simulations over a larger domain in order to improve statistics -> 1D water budget simulations for explaining the dependence
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