Latitudinal dependence of heat transport in turbulent geostrophic convection

Abstract

Latitudinal variations in turbulent heat flux play a key role in the thermal and magnetic evolution of rapidly rotating planets and stars. Although global spherical-shell simulations have documented such variations, explicit latitude-dependent scaling relations for heat transport have remained elusive. Here we employ the rotating Rayleigh-B\'enard convection (RRBC) framework with tilted rotation and gravity axes to model convection at different latitudes in the geostrophic regime. We derive scaling relations for the latitude dependence of convective length scales () and the Nusselt number Nu(). At high latitudes, the scalings Nu -4/3 (near onset) and Nu -4 (above onset) emerge, while at low latitudes Nu 4. These predictions are validated against direct numerical simulations of convection in a spherical shell. The results provide a quantitative framework for regional thermal transport in planetary and stellar interiors and establish a unified interpretation of spherical convection that connects naturally with planar RRBC turbulence.