Penetration of boundary-driven flows into a rotating spherical thermally-stratified fluid

Abstract

Motivated by the dynamics within terrestrial bodies, we consider a rotating, strongly thermally stratified fluid within a spherical shell subject to a prescribed laterally inhomogeneous heat-flux condition at the outer boundary. Using a numerical model, we explore a broad range of three key dimensionless numbers: a thermal stratification parameter (the relative size of boundary temperature gradients to imposed vertical temperature gradients), 10-3 S 104, a buoyancy parameter (the strength of applied boundary heat flux anomalies), 10-3 B 106, and the Ekman number (ratio of viscous to Coriolis forces), 10-6 E 10-4. We find both steady and time-dependent solutions and delineate the temporal regime boundaries. We focus on steady-state solutions, for which a clear transition is found between a low S regime, in which buoyancy dominates dynamics, and a high S regime, in which stratification dominates. For the latter case, the radial and horizontal velocities scale respectively as ur S-1, uh S-34\ B14 and are confined to boundary-induced flow within a thin layer of depth (S\ B)-14 at the outer edge of the domain. For the Earth, if lower-mantle heterogeneous structure is due principally to chemical anomalies, we estimate that the core is in the high-S regime and steady flows arising from strong outer-boundary thermal anomalies cannot penetrate the stable layer. However, if the mantle heterogeneities are due to thermal anomalies and the heat-flux variation is large, the core will be in a low-S regime in which the stable layer is likely penetrated by boundary-driven flows.