Stability of differentially heated flow from a rotating sphere

We present results on the flow of a thin fluid layer over a rotating sphere having a surface temperature that varies in the latitudinal direction. The fluid is taken to be viscous, incompressible and Newtonian while the flow is assumed to possess both azimuthal and equatorial symmetry. The governing Navier-Stokes and energy equations are formulated in terms of a stream function and vorticity and are solved subject to no-slip boundary conditions. An approximate analytical solution for the steady-state flow has been derived and is compared with numerical solutions to the steady and limiting unsteady equations. For small Rayleigh numbers these solutions are found to be in close agreement. However, as the Rayleigh number is increased noticeable differences occur. A numerical solution procedure is presented and a linear stability analysis has been conducted to predict the onset of instability. Good agreement between the theoretical predictions and the observed numerical simulations was found. Differentially heated flow of a thin fluid layer from a rotating sphere has been investigated.A numerical solution procedure for solving the steady and unsteady equations has been proposed.An approximate analytical solution has been derived.A linear stability analysis has estimated a theoretical value for the onset of instability.Good agreement was found between numerical, analytical and theoretical results.