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7 September 2010

Further Single-Column Testing and Implementation into the COSMO Model of the TKE-Scalar Variance Second-Order Turbulence-Convection Scheme. Ekaterina Machulskaya and Dmitrii Mironov German Weather Service, Offenbach am Main, Germany (ekaterina.machulskaya@dwd.de, dmitrii.mironov@dwd.de).

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7 September 2010

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  1. Further Single-Column Testing and Implementation into the COSMO Model of the TKE-Scalar Variance Second-Order Turbulence-Convection Scheme Ekaterina Machulskayaand Dmitrii Mironov German Weather Service, Offenbach am Main, Germany (ekaterina.machulskaya@dwd.de, dmitrii.mironov@dwd.de) 7 September 2010

  2. Single-column tests: dry convective PBL, nocturnal stratocumuli, shallow cumuli, stably-stratified PBL Modified statistical SGS cloud scheme: parallel experiments TKE-scalar variance scheme within a full-fledged COSMO model: implementation, parallel experiment, problems Conclusions and outlook Outline

  3. Single-Column Tests: Dry Convective PBL Mean potential temperature in shear-free convective PBL. Red– TKE scheme, blue– TKE-scalar variance scheme, blackdashed– LES data.

  4. Single-Column Tests: Nocturnal Stratocumuli Fractional cloud cover (left) and cloud water content (middle) in DYCOMS-II. Red – TKE scheme, blue – TKE-scalar variance scheme. Black solid curve in the right figure shows LES data.

  5. Single-Column Tests: Shallow Cumuli skewed Gaussian skewed Gaussian Fractional cloud cover (upper row) and cloud water content (lower row) in BOMEX. Red – TKE scheme, blue – TKE-scalar variance scheme. Black solid curves in the middle figures show LES data.

  6. Single-column tests: shallow cumuli (cont’d) Potential temperature variance (two left panels) and total water variance (two right panels) in BOMEX. Red – TKE scheme, blue – TKE-scalar variance scheme. Black solid curves in the middle figures show LES data.

  7. Single-column tests: shallow cumuli (cont’d) Cloud fraction 1 Important! Non-Gaussian correction is introduced into the expression for the buoyancy flux in the TKE equation 0.5 Linear approximation of the error function (Gaussian distribution) Exponential tail 0 Normalised saturation deficit Strong mean undersaturation = shallow cumuli case

  8. Modified Statistical SGS Cloud Scheme: Parallel Experiments Exp 7680 – COSMO-EU model with modified SGS cloud scheme, January 2010 Exp 7692 – COSMO-EU model with modified SGS cloud scheme, June 2010 Pressure over COSMO-EU domain in June 2010 (00UTC forecasts). Red – Exp7692, blue – COSMO-EU.

  9. Modified Statistical SGS Cloud Scheme: Parallel Experiments (cont’d) Exp 7680, COMO-EU, January 2010 (00UTC forecasts) Verification over COSMO-DE domain TD2m deficit T2m

  10. Modified Statistical SGS Cloud Scheme: Parallel Experiments (cont’d) COSMO-EU domain, June 2010 total cloud cover low-level cloud cover red – Exp7692, blue – COSMO-EU routine

  11. TKE-scalar variance scheme within a full-fledged COSMO model TKE-scalar variance scheme is implemented into full-fledged three-dimensional COSMO model Parallel experiments are being performed • Exp 7771 – with Gaussian SGS cloud scheme • Exp 7778 – with modified (skewed) SGS cloud scheme Problems • numerical stability (hope to improve the situation using non-local formulation for turbulence length scale) • more physically sound parameterisation of non-Gaussian effects within the SGS cloud scheme is needed

  12. LES and Modelling of SBL over Heterogeneous and Homogeneous Surfaces by D. Mironov, P. Sullivan (NCAR) and E. Machulskaya Blue – homogeneous SBL, red – heterogeneous SBL.

  13. Tiled TKE-Temperature Variance Closure Model • Transport (prognostic) equations for TKE and for the temperature variances including third-order transport • Algebraic (diagnostic) formulations for temperature flux, for the Reynolds-stress components, and for turbulence length scale • Tile approach where different tiles have different surface temperature • Surface fluxes are computed as weighted means of fluxes over individual tiles • <w’’2> is non-zero at the surface in heterogeneous SBL • Input parameters of numerical experiments are similar to LES (except for piece-wise vs. sinusoidally varying surface temperature)

  14. Tiled TKE-Temperature Variance Model: Results Blue – homogeneous SBL, red – heterogeneous SBL.

  15. Single-column tests show that the use of TKE-scalar variance scheme brings about some improvements as to fractional cloud cover, second-moment profiles, and evolution of turbulence moments in time, although problems remain Modified SGS statistical cloud scheme (effect of shallow cumuli à la Bechtold et al. 1995) is favourably tested through parallel experiments; scores are neutral to slightly positive TKE-scalar variance scheme is implemented into full-fledged three-dimensional COSMO model, parallel experiment is being performed, performance is monitored, results of verification will be reported later Comprehensive testing through parallel experiments (key issues: numerical stability, computational efficiency), preparation of documentation Improve a parameterisation of the turbulence length/time scale (e.g. non-local vs. Blackadar) Improve description of non-Gaussian effects within the SGS statistical cloud scheme (Bechtold et al. 1995, modifications do not seem to be sufficient) Conclusions and Outlook

  16. Thank you for your attention! Acknowledgements: Vittorio Canuto, Peter Bechtold, Sergey Danilov, Evgeni Fedorovich, Jochen Förstner, Vladimir Gryanik, Thomas Hanisch, Donald Lenschow, Chin-Hoh Moeng, Ned Patton, Pier Siebesma, Peter Sulluvan, Jeffrey Weil, and Yun-Ichi Yano.

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