Plumes in turbulent convection

2. Plumes in turbulent convection A short summary of convection Clustering of convective plumes The Prandtl problem A. Provenzale, ISAC-CNR Torino and CIMA, Savona

3. Rayleigh-Benard convection:

4. Rayleigh-Benard convection: Important parameters: R = ga D3DT / nk s = n / k a = L / D

5. Rayleigh-Benard convection: If R < Rcritconduction T(x,y,z,t)=Tcond(z) (u,v,w)=(0,0,0) If R > Rcritconvection T= Tcond + q (u,v,w) non zero

6. Rayleigh-Benard convection:

7. Rayleigh-Benard convection:

8. Rayleigh-Benard convection: Linear stability analysis Weakly nonlinear expansions “Turbulent” convection

9. Convective patterns: Photo by Hezi Yizhaq, Sede Boker, Negev desert

10. Turbulent convection (s=0.71, a=2p, R=107)

11. Turbulent convection (R=106):

12. Turbulent convection (s=0.71, a=2p, R=107)

13. Turbulent convection (s=0.71, a=2p, R=107)

14. Turbulent convection (s=0.71, a=2p, R=107)

15. Turbulent convection: Statistical properties and transition from soft to hard turbulence Scaling of the heat transport: Nu vs R Nu = 1 + < wq >

16. Turbulent convection: Dynamics of convective plumes

17. Turbulent convection: Formation of large-scale structure and clustering of convective plumes

18. Turbulent convection: Formation of large-scale structure and mean shear (wind) Krishnamurti and Howard (1981) Massaguer, Spiegel and Zahn (1992) Elperin, Kleeorin, Rogachevskii and Zilitinkevish (2003) Hartlep, Tilgner and Busse (2003) Parodi, von Hardenberg, Passoni, Spiegel, Provenzale (2003)

19. Clustering of convective plumes:

20. Clustering of convective plumes:

21. Clustering of convective plumes:

22. Clustering of convective plumes:

23. Clustering of convective plumes:

24. Clustering of convective plumes:

25. Turbulent RB convection undergoesa process of inverse energy cascadefrom the scales of the linear instabilityto the largest scales (box size)Once reached an approximate k-5/3 spectrum,the system becomes statistically stationary(is there an upper scales where the cascade stops?)

26. It is not a mean shear ( k = 0 )but rather a circulation at the largest scalesTurbulent convection is either non-stationaryor dominated by finite-domain effectsThe large-scale structures areclusters of individual plumes

27. What causes the clustering ?

28. Option 1: attraction of same-sign plumes

29. Option 2: the interplay of the lower and upper boundary layersby the agency of plumes

30. Other view:The fixed-flux instabilityof a coarse-grained field( with Reff << R )

31. Is RB convection a good model fornatural convective processes ?Yes, as a first step (e.g. plumes)No, for proper understanding

32. Most natural convective flowshave no up-down symmetryReasons:non-Boussinesqnon symmetric boundary conditions

33. Penetrative convection

34. Penetrative convection

35. Solar granulation

36. Tropical convective precipitation GATE 1 data set. D= 4 km, L=256 km, Dt=15 min

37. “True” dynamics:turbulent, moist, non-Boussinesq precipitating convectionCan we find a simplified dynamical model ?

38. The Prandtl problem Prandtl (1925)

39. The Prandtl problem A Parodi, KA Emanuel, A Provenzale (2003)

40. The Prandtl problem

41. The Prandtl problem Heat flux

42. The Prandtl problem Average temperature profile

43. The Prandtl problem

44. The Prandtl problem

45. The Prandtl problem

46. The Prandtl problem

47. The Prandtl problem P(x,y,t) is taken as a proxy for convective rainfall

48. The Prandtl problem

49. The Prandtl problemstill a long way to go,but the results are intriguing.Linear stability, weakly nonlinear analysis,properties of the turbulent plumes,particle transport.And, then, addition of moisture.