English

Rapidly Rotating Wall-Mode Convection

Fluid Dynamics 2025-08-27 v4 Dynamical Systems Pattern Formation and Solitons

Abstract

In the rapidly rotating limit, we derive a balanced set of reduced equations governing the strongly nonlinear development of the convective wall-mode instability in the interior of a general container. The model illustrates that wall-mode convection is a multiscale phenomenon where the dynamics of the bulk interior diagnostically determine the small-scale dynamics within Stewartson boundary layers at the sidewalls. The sidewall boundary layers feedback on the interior via a nonlinear lateral heat-flux boundary condition, providing a closed system. Outside the asymptotically thin boundary layer, the convective modes connect to a dynamical interior that maintains scales set by the domain geometry. In many ways, the final system of equations resembles boundary-forced planetary geostrophic baroclinic dynamics coupled with barotropic quasi-geostrophic vorticity. The reduced system contains the results from previous linear instability theory but captured in an elementary fashion, providing a new avenue for investigating wall-mode convection in the strongly nonlinear regime. We also derive the dominant Ekman-flux correction to the onset Rayleigh number for large Taylor number, Ra31.8Ta1/24.43Ta5/12+O(Ta1/3)\textit{Ra} \approx 31.8 \,\textit{Ta}^{1/2} - 4.43 \,\textit{Ta}^{5/12} + \mathcal{O}(\textit{Ta}^{1/3}) for no-slip boundaries. However, we find that the linear onset in a finite cylinder differs noticeably compared to a Cartesian channel. We demonstrate some of the reduced model's nonlinear dynamics with numerical simulations in a cylindrical container.

Keywords

Cite

@article{arxiv.2409.20541,
  title  = {Rapidly Rotating Wall-Mode Convection},
  author = {Geoffrey M. Vasil and Keaton J. Burns and Daniel Lecoanet and Jeffrey S. Oishi and Benjamin P. Brown and Keith Julien},
  journal= {arXiv preprint arXiv:2409.20541},
  year   = {2025}
}

Comments

44 pages, 14 figures. Accepted, J. Fluid Mech

R2 v1 2026-06-28T19:02:42.940Z