Oblate electron holes are not attributable to anisotropic shielding

Author(s)

Hutchinson, Ian H.

Abstract

Shielding mechanisms' influence on the ratio of perpendicular to parallel scale lengths of multidimensional plasma electron hole equilibria are analyzed theoretically and computationally. It is shown that the ``gyrokinetic'' model, invoking perpendicular polarization, is based on a misunderstanding and cannot explain the observational trend that greater transverse extent accompanies lower magnetic field. Instead, the potential in the wings of the hole, outside the region of trapped-electron depletion, has isotropic shielding giving $\phi\propto {\rm e}^{-r/L}/r$, with the shielding length $L$ equal to the Debye length for holes much slower than the electron thermal speed. Particle in cell simulations confirm the analysis. Trapped electron charge distribution anisotropy must therefore instead underlie the oblate shape of electron holes.

Description

Submitted for publication in Physics of Plasmas

Date issued

2021-02

URI

https://hdl.handle.net/1721.1/158593

Department

Massachusetts Institute of Technology. Plasma Science and Fusion Center

Journal

Physics of Plasmas

Publisher

AIP

Other identifiers

21ja102