Effects of transitional orbit magnetization on transport and current in Z pinches

TL;DR

This paper investigates how the transition from cyclotron to betatron orbits near the magnetic null in Z pinches affects plasma transport, revealing a coexistence region where classical theories fail and betatron flux dominates.

Contribution

It introduces a magnetization parameter to quantify orbit regimes and characterizes the transitional transport behavior in Z pinch plasmas.

Findings

Classical magnetized transport theory fails in the transitional region.

Betatron orbits support the diamagnetic drift reversal.

Kinematic diffusivity remains constant near the null.

Abstract

The azimuthal self-magnetic field of the ideal Z pinch contains a central magnetic null. Trajectories around this null govern transport in the core. Particles follow cyclotron orbits when the guiding-center approximation holds. Approaching the field null, where the ordinary guiding-center regime breaks down, particles exhibit trajectories called, in some historical contexts, betatron orbits. We quantify transitional magnetization between cyclotron and betatron orbits by a magnetization parameter that decomposes phase space into these orbit regimes. Considering the distribution of all orbits, this phase-space decomposition reveals a transitional magnetization region wherein both populations coexist. Classical magnetized transport theory fails within this region, where the diamagnetic drift reverses. The drift flux is instead supported by the flux of betatron orbits. Kinematic diffusivity remains approximately constant rather than diverging at the null. These transport modifications are governed solely by the number density per unit length in the ideal pinch.