Analytical model of three regimes of cold cathode breakdown in helium

TL;DR

This paper presents an analytical model for three regimes of cold cathode breakdown in helium at very high voltages, incorporating effects of fast neutrals, charge exchange, and ionization, validated against simulations and experiments.

Contribution

The paper introduces a novel analytical model capturing three breakdown regimes in helium, emphasizing the role of fast neutrals and charge exchange at high voltages.

Findings

Identified three regimes of breakdown based on ionization sources.

The model accurately predicts breakdown behavior up to 1000 kTd electric field.

The Paschen curve exhibits a double-valued shape with a branch point near 200 kV.

Abstract

An analytical model has been developed to map out the low-pressure (left-hand) branch of the Paschen curve at very high voltage when electrons are in the runaway regime and charge exchange/ionization avalanche by ions and fast neutral atoms becomes important. The model has been applied to helium gas between parallel-plate electrodes, at potentials ranging in magnitude between 10 and 1000 kilovolt. The respective value of reduced electric field E/n varies in the range of 50-6000kTd, with reduced density nd (where n is the gas density and d is the inter-electrode distance) on the order of 10^20 m^-2. For fast neutral atoms produced via charge exchange, the following interactions prove essential to understanding the breakdown mechanism: contribution to impact ionization, strongly anisotropic scattering in collisions with background atoms,and backscattering (of both atoms and ions, which become neutralized) from the cathode. Three regimes of the breakdown have been identified according to relative share of impact ionization by electrons, by ions, and by fast neutrals. In the fast-neutral regime of particular interest here, the ionization avalanche is directed from anode towards cathode. It is initiated by the fast neutral beam backscattered from the cathode, and charge multiplication occurs through multiple successive cycles of ionization and charge exchange. Further, the double-valued shape of the Paschen curve with a branch point near 200 kV is found to be due to heavy species undergoing a transition to runaway regime. The analytical Paschen curve is compared to those obtained with a detailed Particle-In-Cell/Monte Carlo (PIC/MCC) simulation, and also to experimental measurements. The model provides accurate predictions for E/n up to ~ 1000 kTd, constrained by availability and quality of required input data.