On the mechanism of ionization oscillations in Hall thrusters

TL;DR

This paper investigates the stability and oscillation mechanisms of ionization oscillations in Hall thrusters by analyzing continuum PDE models, revealing conditions under which breathing mode oscillations occur and their dependence on ion back-flow region width.

Contribution

It introduces a continuum PDE model for plasma and neutral densities in Hall thrusters, extending the standard predator-prey model, and identifies conditions leading to breathing mode oscillations.

Findings

The 1-D PDE model is stable and non-oscillatory under certain boundary conditions.

A reduced PDE model exhibits oscillations when ion back-flow is included.

Breathing mode frequency correlates strongly with the width of the ion back-flow region.

Abstract

Low frequency ionization oscillations involving plasma and neutral density (breathing modes) are the most violent perturbations in Hall thrusters for electric propulsion. Because of its simplicity, the zero-dimensional (0-D) predator-prey model of two nonlinearly coupled ordinary differential equations for plasma and neutral density has been often used for the characterization of such oscillations and scaling estimates. We investigate the properties of its continuum analog, the one-dimensional (1-D) system of two nonlinearly coupled equations in partial derivatives (PDE) for plasma and neutral density. This is a more general model, of which the standard 0-D predator-prey model is a special limit case. We show that the 1-D model is stable and does not show any oscillations for the boundary conditions relevant to Hall thruster and the uniform ion velocity. We then propose a reduced 1-D model based on two coupled PDE for plasma and neutral densities that is unstable and exhibit oscillations if the ion velocity profile with the near the anode back-flow (toward the anode) region is used. Comparisons of the reduced model with the predictions of the full model that takes into account the self-consistent plasma response show that the main properties of the breathing mode are well captured. In particular, it is shown that the frequency of the breathing mode oscillations is weakly dependent on the final ion velocity but shows a strong correlation with the width of the ion back-flow region.