Characterization of Argon Plasma in a variable Multi-pole line Cusp Magnetic Field Configuration

TL;DR

This study provides a comprehensive characterization of argon plasma within a variable multi-pole line cusp magnetic field, demonstrating how magnetic field adjustments influence plasma confinement, density, and stability.

Contribution

It introduces a detailed experimental and simulation analysis of VMMF effects on plasma properties, highlighting controllable null regions and improved confinement mechanisms.

Findings

Magnetic field change rate is higher with vacoflux-50 core (7.53 G/A) than air core (2.15 G/A).

Increasing magnetic field enhances plasma density, confinement time, and stability.

VMMF enables control over null region size and plasma uniformity.

Abstract

This paper demonstrates a detailed characterization of argon plasma in a variable multi-pole line cusp magnetic field (VMMF). The VMMF has been produced by placing six electromagnets (with embedded profiled vacoflux-50 core) over a large cylindrical volume (1 m axial length and 40 cm diameter). The magnetic field have been measured by hall probe method and compared with simulated magnetic field by performing simulation using FEMM tools. Results from magnetic field simulation indicate that the rate of change of pole magnetic field (maximum magnetic field) with respect to magnet current for vacoflux-50 core is high (7.53 G/A) as compared to the simple air core electromagnet (2.15 G/A). The area of the nearly field free region (null region) in the chamber volume can be controlled without changing a number of pole magnets. From the experimental results, it has been observed that in this field configuration the confinement of the primary electrons increases and leak width of plasma decreases with increasing the magnetic field. Thus the mean density, particle confinement time and the stability of the plasma increase with increasing magnetic field. In addition to this, it has been found that the radial uniformity of the plasma density explicitly depends on the VMMF. It is also shown that the VMMF controls the scavenging of confined primary electrons and confinement of primary electron increased with magnetic field which helps to boost up the plasma density.