# Comparative Study of the Surface Potential of Magnetic and Non-magnetic   Spherical Objects in a Magnetized RF Discharge Plasma

**Authors:** Mangilal Choudhary, Roman Berger, Slobodan Mitic, Markus H. Thoma

arXiv: 1901.10955 · 2020-10-28

## TL;DR

This study measures and compares the surface floating potential of magnetic and non-magnetic spherical objects in a magnetized plasma, revealing how magnetic fields and material properties influence charge accumulation.

## Contribution

It provides new insights into how magnetic properties and magnetic field strength affect the surface potential of spherical probes in plasma environments.

## Key findings

- Magnetic spheres attain higher negative surface potential than non-magnetic spheres.
- Surface potential varies with magnetic field strength, peaking at B < 0.05 T.
- Size has minimal effect on surface potential above B > 0.03 T.

## Abstract

We report measurements of the time-averaged surface floating potential of magnetic and non-magnetic spherical probes (or large dust particles) immersed in a magnetized capacitively coupled discharge. In this study, the size of the spherical probes is taken greater than the Debye length. The surface potential of a spherical probe first increases, i.e. becomes more negative at low magnetic field (B $<$ 0.05 T), attains a maximum value and decreases with further increase of the magnetic field strength (B $>$ 0.05 T). The rate of change of the surface potential in the presence of a B-field mainly depends on the background plasma and types of material of the objects. The results show that the surface potential of the magnetic sphere is higher (more negative) compared to the non-magnetic spherical probe. Hence, the smaller magnetic sphere collects more negative charges on its surface than a bigger non-magnetic sphere in a magnetized plasma. The different sized spherical probes have nearly the same surface potential above a threshold magnetic field (B $>$ 0.03 T), implicating a smaller role of size dependence on the surface potential of spherical objects. The variation of the surface potential of the spherical probes is understood on the basis of a modification of the collection currents to their surface due to charge confinement and cross-field diffusion in the presence of an external magnetic field.

## Full text

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## Figures

25 figures with captions in the complete paper: https://tomesphere.com/paper/1901.10955/full.md

## References

68 references — full list in the complete paper: https://tomesphere.com/paper/1901.10955/full.md

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Source: https://tomesphere.com/paper/1901.10955