Transition of blue-core helicon discharge

TL;DR

This paper investigates the transition phenomena in blue-core helicon discharges, combining experimental diagnostics and electromagnetic modeling to reveal changes in plasma parameters, wave fields, and instabilities during the transition.

Contribution

It provides the first detailed analysis of blue-core transition characteristics using advanced diagnostics and electromagnetic simulations, enhancing understanding of plasma behavior in helicon discharges.

Findings

Electron density increases significantly during transition.

Electron temperature exhibits opposite trend to density, decreasing as density increases.

Wave field structures change notably during the transition, affecting power absorption.

Abstract

This study explores the transitional characteristics of blue-core helicon discharge, which to our knowledge was not particularly focused on before. Parameters are measured on recently built advanced linear plasma device, i.e. Multiple Plasma Simulation Linear Device (MPS-LD) by various diagnostics including Langmuir probe, optical emission spectrometer, and standard high-speed camera. It is found that the jump direction of electron density (from low level to high level) is opposite to that of electron temperature (from high level to low level). Electron density increases significantly and the radial profile becomes localized near the axis when the blue-core transition occurs. With increased field strength, electron density increases whereas electron temperature drops. The radial profile of electron temperature looks like a ``W" shape, i.e. minimizing around the edge of blue-core column. Electron density increases with background pressure, while electron temperature peaks around certain pressure value. High-speed videos show that the plasma column oscillates radially and experiences azimuthal instabilities with high rate once entered blue-core mode. An electromagnetic solver (EMS) based on Maxwell's equations and a cold-plasma dielectric tensor is also employed to compute the wave field and power absorption during blue-core transition, to provide more details that are valuable for understanding the transitional physics but not yet available in experiment. The results show that wave field in both radial and axial directions changes significantly during the transition, its structure differs from antenna to downstream, and the power dependence of wave magnetic field is overall opposite to that of wave electric field. This work presents comprehensive characteristics of the transitional blue-core discharge and is important to both physics understanding and practical applications.