Instability and Turbulent Relaxation in a Stochastic Magnetic Field

TL;DR

This paper analyzes how stochastic magnetic fields influence instability dynamics, turbulence, and magnetic braking in plasma, providing new insights into turbulence locking and testable predictions for experimental validation.

Contribution

It introduces a stochastic differential equation approach to instability analysis in magnetic fields, revealing turbulence locking and magnetic braking effects with detailed predictions.

Findings

Turbulence locks onto ambient stochastic magnetic perturbations.

Magnetic perturbations induce a magnetic braking effect on vorticity.

The study provides testable predictions linking theory, simulations, and experiments.

Abstract

An analysis of instability dynamics in a stochastic magnetic field is presented for the tractable case of the resistive interchange. Externally prescribed static magnetic perturbations convert the eigenmode problem to a stochastic differential equation, which is solved by the method of averaging. The dynamics are rendered multi-scale, due to the size disparity between the test mode and magnetic perturbations. Maintaining quasi-neutrality at all orders requires that small-scale convective cell turbulence be driven by disparate scale interaction. The cells in turn produce turbulent mixing of vorticity and pressure, which is calculated by fluctuation-dissipation type analyses, and are relevant to pump-out phenomena. The development of correlation between the ambient magnetic perturbations and the cells is demonstrated, showing that turbulence will `lock on' to ambient stochasticity. Magnetic perturbations are shown to produce a magnetic braking effect on vorticity generation at large scale. Detailed testable predictions are presented. The relations of these findings to the results of available simulations and recent experiments are discussed.