Partial ionisation cross sections for the binary-encounter Bethe model

TL;DR

This paper evaluates the binary-encounter Bethe (BEB) model's accuracy in calculating partial ionisation cross sections using experimental thresholds, improving predictions relevant for plasma physics.

Contribution

It introduces the use of experimental ionisation thresholds in the BEB model to enhance the accuracy of partial ionisation cross sections.

Findings

Improved partial cross section calculations with experimental thresholds.

Better predictions of ionic states relevant for plasma modeling.

Potential for more accurate optical and non-radiative transition modeling.

Abstract

The original binary-encounter Bethe model of Kim and Eugene Rudd (1994 Phys. Rev. A 50 3954-67) has proven to be an accurate analytical representation of total impact ionisation cross sections of electrons colliding with atoms and molecules. It is based on a decomposition into partial ionisation cross sections from electrons in bound orbitals. Despite the model's accuracy for total ionisation, its individual partial cross sections for ionisation rely on thresholds calculated theoretically which systematically overestimate the experimental orbital binding energies. Here, we examine the BEB model's performance when based on experimental ionisation thresholds. The resulting partial cross sections of the various final (excited) ionic states produced could help to prefigure subsequent optical radiations and non-radiative transitions in models of plasma physics.