Hirlam Physics Developments

1. Sander Tijm Hirlam Project leader for physics Hirlam Physics Developments

2. Overview • Results of this year • Verification • Shallow convection • Turbulence and convection for mesoscale • Tuning of synoptic scale model

3. Mesoscale Verification Surface Turbulence & shallow convection Deep convection? Radiation Synoptic scale EPS & boundaries Verification Surface (tuning) Turbulence Shallow convection Deep convection Radiation Wave drag Hirlam physics developments

4. Results this year • Hirlam physics in IFS (Convection, turbulence and radiation, Sass, Rontu and Niemela) • Moist CBR (Sass & Tijm) • MSO/SSO (Rontu) • Surface scheme (snow and forest, talk of Stefan after this one) • Sloping surfaces radiation (Senkova) • Stable PBL (GABLS, De Bruijn, Perov & friends) • Snow on ice (Vihma) • Lake model (Kourzeneva & Tisler) • Urban characteristics (Baklanov & Mahura)

5. Moist CBR • Impact on cloud water profiles

6. Moist CBR • Impact on precipitation

7. Snow scheme

8. Verification • Verification working group to check physics of mesoscale model • Cooperation with Aladin • Focus on relatively normal weather, which is challenge for physics • List of cases and progress of work can be found on: http://www.knmi.nl/~tijm/Verif/Verifworkg.html • Verification of models against observations • Model intercomparison • Baseline for future model improvement

9. Verification

10. Cloud top temperatures (Zingerle) KF-RK REF Obs

11. Entrainment/Detrainment • Overprediction of high clouds • Too much deep convection, too little convection of intermediate depth • Too little entrainment (lowering of updraft temperature) and/or detrainment (stopping updraft mass flux) • Can also be seen in shallow cumulus

12. Specific humidity profiles for ARM with LES (left) and Hirlam 1D using =z-1 and =0.00275 Shallow convection (De Rooy)

13. Shallow convection • Mass flux profiles for LES (left) and =z-1 + =0.00275 (right)

14. Shallow convection • Massflux profiles for LES (left) and =z-1 + new  (right) where  depends on cloud depth and critical fraction

15. Shallow convection qt profiles for ARM with LES (left) and Hirlam SCM (right) with =1/z and new  formulation

16. zinv EDMF scheme (Siebesma) • Nonlocal (Skewed) transport through strong updrafts in clear and cloudy boundary layer by advective Mass Flux (MF) approach • Remaining (Gaussian) transport done by an Eddy Diffusivity (ED) approach MF ED

17. Use LES to derive updraft model in clear boundary layer. 0 h (km) 1 0 5 x(km) Updraft at height z composed of those grid points that contain the highest p% of the vertical velocities: p=1%,3%,5%:

18. EDMF scheme • One scheme for boundary layer and cumulus convection • Will be developed within AROME framework, as an option • Cooperation with ECMWF • After successful implementation in mesoscale model, incorporate in synoptic scale model to limit boundary effects

19. Surface developments • New surface scheme (Gollvik) for synoptic scale • Extension of surface scheme with lake model (Kourzeneva) • Extension with improved description of snow on ice (Vihma) • Urban impact to be included (Mahura and Baklanov) • Tuning of surface characteristics (Garcia)

20. Modeled temperature, sensitivity to lake depth(Flake model, Kourzeneva)

21. Tuning of syn. Hirlam • Sytematic errors in synoptic scale Hirlam: • too much fog • too many and intense small scale lows • too strong convection dynamics feedback (noisy pressure pattern) • Overestimation of evaporation over sea may be an important factor in the development of these phenomena, together with: • Vertical diffusion in stable and neutral conditions • Deep convection parameterization

22. Tuning of syn. Hirlam

23. Small scale developments

24. Summary • Many developments for turbulence, shallow and deep convection, surface modelling. • Shift of main effort towards the mesoscale physics • Synoptic scale remains important, for mesoscale boundaries and SREF • Synoptic physics as close as possible to mesoscale physics, to reduce boundary effects