Collisional whistler instability and electron temperature staircase in inhomogeneous plasma

TL;DR

This paper develops a new theoretical framework for understanding how collisional whistler waves influence electron temperature profiles in high-beta plasmas, revealing mechanisms for temperature staircase formation and heat flux suppression.

Contribution

It introduces a Wigner--Moyal formalism for collisional whistler instability, showing how these waves can stabilize temperature structures and regulate heat transport in collisional plasmas.

Findings

Whistler waves can re-arrange electron temperature profiles.

Stable temperature staircases can form in high-beta plasmas.

Whistler waves can suppress electron heat flux via the Ettingshausen effect.

Abstract

High-beta magnetized plasmas often exhibit anomalously structured temperature profiles, as seen from galaxy cluster observations and recent experiments. It is well known that when such plasmas are collisionless, temperature gradients along the magnetic field can excite whistler waves that efficiently scatter electrons to limit their heat transport. Only recently has it been shown that parallel temperature gradients can excite whistler waves also in collisional plasmas. Here we develop a Wigner--Moyal theory for the collisional whistler instability starting from Braginskii-like fluid equations in a slab geometry. This formalism is necessary because, for a large region in parameter space, the fastest-growing whistler waves have wavelengths comparable to the background temperature gradients. We find additional damping terms in the expression for the instability growth rate involving inhomogeneous Nernst advection and resistivity. They (i) enable whistler waves to re-arrange the electron temperature profile via growth, propagation, and subsequent dissipation, and (ii) allow non-constant temperature profiles to exist stably. For high-beta plasmas, the marginally stable solutions take the form of a temperature staircase along the magnetic field lines. The electron heat flux can also be suppressed by the Ettingshausen effect when the whistler intensity profile is sufficiently peaked and oriented opposite the background temperature gradient. This mechanism allows cold fronts without magnetic draping, might reduce parallel heat losses in inertial fusion experiments, and generally demonstrates that whistler waves can regulate transport even in the collisional limit.