The Critical Role of Isopotential Surfaces for Magnetostatic Ponderomotive Forces

Abstract

By producing localized wave regions at the ends of an open-field-line magnetic confinement system, ponderomotive walls can be used to differentially confine different species in the plasma. Furthermore, if the plasma is rotating, this wall can be magnetostatic in the lab frame, resulting in simpler engineering and better power flow. However, recent work on such magnetostatic walls have shown qualitatively different potentials than those found in the earlier, non-rotating theory. Here, using a simple slab model of a ponderomotive wall, we resolve this discrepancy. We show that the form of the ponderomotive potential in the co-moving plasma frame depends on the assumption made about the electrostatic potential in the lab frame. If the lab-frame potential is unperturbed by the magnetic oscillation, one finds a parallel-polarized wave in the co-moving frame, while if each field line remains equipotential throughout the perturbation region, one finds a perpendicularly-polarized wave. This in turn dramatically changes the averaged ponderomotive force experienced by a charged particle along the field line: not only its scaling, but also its direction.