Toroidal and poloidal energy in rotating Rayleigh-B\'enard convection

Abstract

We consider rotating Rayleigh-B\'enard convection of a fluid with a Prandtl number of Pr = 0.8 in a cylindrical cell with an aspect ratio = 1/2. Direct numerical simulations were performed for the Rayleigh number range 105 ≤ Ra ≤ 109 and the inverse Rossby number range 0 ≤ 1/Ro ≤ 20. We propose a method to capture regime transitions based on the decomposition of the velocity field into toroidal and poloidal parts. We identify four different regimes. First, a buoyancy dominated regime occurring as long as the toroidal energy etor is not affected by rotation and remains equal to that in the non-rotating case, e0tor. Second, a rotation influenced regime, starting at rotation rates where etor > e0tor and ending at a critical inverse Rossby number 1/Rocr that is determined by the balance of the toroidal and poloidal energy, etor = epol. Third, a rotation dominated regime, where the toroidal energy etor is larger than both, epol and e0tor. Fourth, a geostrophic turbulence regime for high rotation rates where the toroidal energy drops below the value of non-rotating convection.