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Numerical experiments with the COSMO Model boundary layer scheme based on a parcel displacement scheme for a turbulent length scale Veniamin Perov and.

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Presentation on theme: "Numerical experiments with the COSMO Model boundary layer scheme based on a parcel displacement scheme for a turbulent length scale Veniamin Perov and."— Presentation transcript:

1 Numerical experiments with the COSMO Model boundary layer scheme based on a parcel displacement scheme for a turbulent length scale Veniamin Perov and Gdaly Rivin Hydrometeorological Centre, Moscow, Russia COSMO 2009, 7-11 September

2 Outline - Specification method of the length scale on the base of Bougeault and Lacarrere approach (BL89) - Use of the method in SCM and LM COSMO models. Preliminary results. - Definition of the new stability functions on the base of spectral theory of turbulence - Summary

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4 Turbulent length scale scheme Blackadar formula, local l then

5 z Schematic view of profiles of potential temperature (black line) and turbulent length scale (Blackadar, red line) for well-mixed layer capped by a strong inversion L

6 z TKE Schematic view of a turbulent length scale scheme based on a parcel displacement (BL89) for a boundary layer scheme of the COSMO model

7 Turbulent length scale scheme Blackadar formula, local l then

8 BL(89) seems physically well founded The length scale of the largest eddies at a given level is determined as a function of the stability profile of the adjacent levels The algorithm relies on the computation of the maximum vertical displacement allowed for a parcel of air having the mean kinetic energy of the level as initial kinetic energy The maximum upward and downward displacement are computed by assuming that the parcel will stop when the cumulated buoyancy acceleration equal the initial kinetic energy (Fig) The method allows the length scale at any level to be affected not only by the stability at this level, but by the effect of remote levels (“non-local” length)

9 Vertical profiles of potential temperature for reference L (red line) and for parcel displacement L (blue dotted line) during GABLS2 experiment. The data of experiment are shown by asterisks

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13 Summary The method for specification of the non-local turbulent length scale base on BL(89) has been implemented in the COSMO model The results of 54h and 78h forecasts show realistic fields of T, RH,U,V, P for low and middle atmosphere The tests for different stratification and different types of clouds will be run for 1-D and 3-D variants in the nearest months Finally, verification of 3-D variant will be produced

14 Thank you for your attention

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16 New stability functions on base of the spectral theory of turbulence

17 Comparison of stability functions calculated from Mellor-Yamada model and from the spectral theory

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