Sheath effects with thermal electrons on the resonance frequency of a DC-biased hairpin probe

TL;DR

This paper investigates how electron temperature affects the sheath dielectric and resonance frequency of a DC-biased hairpin probe, revealing that higher electron temperatures shift and broaden the resonance peak, validated experimentally.

Contribution

It introduces the impact of electron temperature on sheath dielectric effects and resonance frequency shifts in hairpin probes, providing new insights into probe diagnostics.

Findings

Electron temperature influences the resonance frequency characteristic curve.

Higher electron temperatures shift the resonance peak to higher bias values.

Experimental validation confirms the theoretical predictions.

Abstract

The dielectric constant of a sheath, whether ionic or electronic, formed around the cylindrical limbs of a hairpin probe, is often considered the same as that of a vacuum. However, this assumption does not hold true for electron sheaths and electron-permeating ionic sheaths, resulting in a deviation of the sheath dielectric constant from that of a vacuum. This deviation significantly influences the effective dielectric between the cylindrical limbs. As a result, it impacts the theoretically estimated resonance frequency characteristic curve of a DC-biased hairpin probe. In this study, we investigate the influence of electron temperature on the sheath dielectric and, consequently, on the resonance frequency characteristic curve. The findings shows that electron temperature primarily determines the resonance frequency characteristic curve. With increasing electron temperature, the peak in the resonance frequency characteristic curve shifts towards higher positive probe bias values and exhibits a broadening near the maxima instead of a sharp peak. This broadening near the maxima has also been validated with an experimentally measured resonance frequency characteristic curve in a capacitively coupled argon discharge.