Helicon waves in a converging-diverging magnetoplasma

TL;DR

This paper investigates helicon wave propagation in a converging-diverging magnetoplasma, revealing wave characteristics, guiding behavior, and amplitude variations influenced by local resonances and plasma geometry.

Contribution

It provides detailed experimental characterization of helicon waves in a converging-diverging plasma, highlighting wave behavior and resonance effects in such geometries.

Findings

Helicon waves follow the m=0 mode and satisfy the dispersion relation.

Wave amplitudes are affected by local resonances and reflections.

Guiding of rf magnetic fields is influenced by the plasma geometry.

Abstract

Waves propagating along a converging-diverging rf magnetoplasma having the characteristics of a bounded m=0 helicon mode are reported and characterised. The discharge features a 30 cm separation between the region of radiofrequency energy deposition by a single loop antenna and the region of maximum magnetic field applied by a pair of coils. With 200 W of rf input power, the resulting plasma exhibits a strong axial plasma density gradient peaking at the magnetic mirror throat where an Ar II blue-core is observed. Two dimensional B-dot probe measurements show that the rf magnetic fields are closely guided by the converging-diverging geometry. The wave is characterised as a m=0 mode satisfying the helicon dispersion relation on-axis with radial boundary conditions approximately matching the radii of the plasma column. Analysis of the wave phase velocity and wave axial damping failed to identify collisionless or collisional wave-plasma coupling mechanisms. Instead, the wave axial amplitude variations can be explained by local wave resonances and possible reflections from localised rapid changes of the refractive index. A Venturi-like effect owing to the funnel-shaped magnetoplasma and conservation of the wave energy may also explain some level of amplitude variations.