Exact and Approximate Solutions for Magnetohydrodynamic Flow Control in Hele-Shaw Cells

Abstract: Consider the motion of a thin layer of electrically conducting fluid, between two closely spaced parallel plates, in a classical Hele-Shaw geometry. Furthermore, let the system be immersed in a uniform external magnetic field (normal to the plates) and let electrical current be driven between conducting probes immersed in the fluid layer. In the present paper, we analyse the ensuing fluid flow at low Hartmann numbers. We first elucidate the mechanism of flow generation both physically and mathematically. We proceed by presenting mathematical solutions for a class of canonical multiply-connected geometries, in terms of the prime function developed by Crowdy (2020). Notably, those solutions can be written explicitly as series, and are thus exact, in doubly-connected geometries. Note that in higher connectivities, the prime function must be evaluated numerically. We then demonstrate how recently developed fast numerical methods may be applied to accurately determine the flow-field in arbitrary geometries when exact solutions are inaccessible.