Based on joint work with X. Ding Cf. Physica A 2006, J. Math Phys june 2007,

1. Chjan Lim RPI, Troy, NY, UShttp://www.rpi.edu/~limc Statistical Equilibrium in large scale atmospheric and planetary flows - exact solns for phase transitions to super-rotation in barotropic and divergent flows coupled to rotating sphere Based on joint work with X. Ding Cf. Physica A 2006, J. Math Phys june 2007, and new book Vorticity, Stat Mech and MC Simulations, Springer Oct 2006

2. Collaborators and acknowledgement • Xueru Ding, PhD student at RPI • Dr. Joseph Nebus, lecturer at NUS Singapore • Support provided by US ARO and DOE

3. Venus Super-Rotation

4. BECondensation to super-rotation

5. Coupled fluid – solid sphere system • Thin fluid shell – nondivergent and divergent – envelopes rotating infinitely massive solid sphere • Fluid assumed inviscid but able to exchange energy and angular momentum with sphere • This complex torque mechanism is not resolved

6. Energy of the Fluid • Due to above modeling assumptions, rest frame energy of the fluid is not a Hamiltonian • No need for that in generalized path-integral approach used here • There is no need for a local in time governing PDE in the statistical mechanics approach in use

7. Restframe energy • For nondivergent barotropic fluid, the energy in the restframe

8. Energy II • Dropping the last – constant term – we get Second term is proportional to angular momentum

9. Energy III

10. Spin Lattice coupled BV Models

11. Coupled BV - constraints

12. Coupled BV – partition function = 0

13. Coupled BV - BECondensation Super-Rotation

14. Coupled BV Monte-Carlo simulation results Sub-Rotation

15. Coupled BV – disordered phase

16. coupledBV – MC phase transitions Mean Nearest Neighbor Parity

17. Coupled BV – transitions II

18. Phase transitions III

19. Coupled BV – MC entropy Based on X. Ding’s algorithm for calculating degeneracy

20. Coupled BV – MC free energy

21. Coupled SW – rotating solid sphere

22. Coupled SW spin lattice models

23. Coupled SW – physical quantities

24. Coupled SW - constraints

25. Coupled SW – partition function

26. Jupiter

27. Transition to subrotating solid-bodymoderate spin

28. Transition pic2 moderate spin

29. Anticyclonic asymmetry I

30. Anticyclonic asymmetry II

31. Anticyclonic dominance III

32. Signs of bands - large spins

33. Red Spot like - very small spin; in southern hemisphere

34. More on Red Spot like II with slightly different constraints; south

35. Red spot like III - small spin large potential enstrophy; south

36. Red spot like IV - negative T; south

37. III Exact solutions – spherical models

38. Spherical model - BEC continued

39. Exact spherical model soln

40. Exact soln continued

41. Exact soln

42. Exact soln to Physical content

43. Theorems with Physical content II

44. Spherical models for coupled SW flows

45. References: • M. Kac and I. Berlin, 1953 spherical model paper Phys Rev 1952 • Feynman, PhD thesis 1943 Princeton U. • Polyakov, Gauge fields and Strings • C. Lim and J. Nebus, Vorticity, Stat Mech and MC simulations, Springer-Verlag book Oct 2006 • Kraichnan JFM 1975 • Work of J. Sommeria 1986 • Work of Tabeling et al • Work of G. van Heijst on 2d no slip square domains • X. Ding and C. Lim, Physica A 2006 • C. Lim, J Math Phys 2007 • C. Lim, SIAM J. Applied Math 2005 • C. Lim, Exact solutions for a statistical equilibrium theory of SW flows coupled to massive rotating sphere, preprint 2006.