Relaxed MHD states of a multiple region plasma

TL;DR

This paper investigates the stability of multiple relaxation region MHD plasmas using variational and tearing mode methods in a cylindrical setup, revealing consistent stability trends and pressure stabilization effects.

Contribution

It provides a comparative analysis of variational and tearing mode treatments for MRXMHD stability, including analytic expressions and stability criteria in a periodic cylinder.

Findings

Variational and tearing mode methods agree on marginal stability for pressure-less plasmas.

Tearing mode analysis identifies ideal MHD unstable solutions with infinite $ abla \

Pressure increases lead to enhanced stability in MRXMHD configurations.

Abstract

We calculate the stability of a multiple relaxation region MHD (MRXMHD) plasma, or stepped-Beltrami plasma, using both variational and tearing mode treatments. The configuration studied is a periodic cylinder. In the variational treatment, the problem reduces to an eigenvalue problem for the interface displacements. For the tearing mode treatment, analytic expressions for the tearing mode stability parameter $\Delta'$, being the jump in the logarithm in the helical flux across the resonant surface, are found. The stability of these treatments is compared for $m=1$ displacements of an illustrative RFP-like configuration, comprising two distinct plasma regions. For pressure-less configurations, we find the marginal stability conclusions of each treatment to be identical, confirming analytic results in the literature. The tearing mode treatment also resolves ideal MHD unstable solutions for which $\Delta' \to \infty$: these correspond to displacement of a resonant interface. Wall stabilisation scans resolve the internal and external ideal kink. Scans with increasing pressure are also performed: these indicate that both variational and tearing mode treatments have the same stability trends with $\beta$, and show pressure stabilisation in configurations with increasing edge pressure. Combined, our results suggest that MRXMHD configurations which are stable to ideal perturbations plus tearing modes are automatically in a stable state. Such configurations, and their stability properties, are of emerging importance in the quest to find mathematically rigorous solutions of ideal MHD force balance in 3D geometry.