Two-dimensional Rayleigh-B\'enard convection without boundaries

Abstract

We study the effects of Prandtl number Pr and Rayleigh number Ra in two-dimensional Rayleigh-B\'enard convection without boundaries, i.e. with periodic boundary conditions. In the limits of Pr 0 and ∞, we find that the dynamics are dominated by vertically oriented elevator modes that grow without bound, even at high Rayleigh numbers and with large scale dissipation. For finite Prandtl number in the range 10-3 ≤ Pr ≤ 102, the Nusselt number tends to follow the `ultimate' scaling Nu Pr1/2 Ra1/2, and the viscous dissipation scales as ε Pr1/2 Ra-1/4. The latter scaling is based on the observation that enstrophy ω2 Pr0 Ra1/4. The inverse cascade of kinetic energy forms the power-law spectrum Eu(k) k-2.3, while the direct cascade of potential energy forms the power-law spectrum Eθ(k) k-1.2, with the exponents and the turbulent convective dynamics in the inertial range found to be independent of Prandtl number. Finally, the kinetic and potential energy fluxes are not constant in the inertial range, invalidating one of the assumptions underlying Bolgiano-Obukhov phenomenology.

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