Extensions and Applications of the Bohm Criterion

TL;DR

This paper compares two approaches to the generalized Bohm criterion, incorporating kinetic effects into sheath theory, and demonstrates their differences through models and simulations, highlighting the impact on ion flow predictions.

Contribution

It provides a detailed comparison of the conventional kinetic Bohm criterion and a fluid-moment hierarchy approach, clarifying their assumptions and applicability.

Findings

Conventional kinetic theory predicts slow ions dominate at the sheath edge.

Fluid moment approach suggests slow ions have little influence.

Electron kinetic effects can lead to subsonic ion flow at the sheath edge.

Abstract

The generalized Bohm criterion is revisited in the context of incorporating kinetic effects of the electron and ion distribution functions into the theory. The underlying assumptions and results of two different approaches are compared: The conventional `kinetic Bohm criterion' and a fluid-moment hierarchy approach. The former is based on the asymptotic limit of an infinitely thin sheath ($\lambda_D/l =0$), whereas the latter is based on a perturbative expansion of a sheath that is thin compared to the plasma ($\lambda_D/l \ll 1$). Here $\lambda_D$ is the Debye length, which characterizes the sheath length scale, and $l$ is a measure of the plasma or presheath length scale. The consequences of these assumptions are discussed in terms of how they restrict the class of distribution functions to which the resulting criteria can be applied. Two examples are considered to provide concrete comparisons between the two approaches. The first is a Tonks-Langmuir model including a warm ion source [Robertson 2009 \textit{Phys.\ Plasmas} {\bf 16} 103503]. This highlights a substantial difference between the conventional kinetic theory, which predicts slow ions dominate at the sheath edge, and the fluid moment approach, which predicts slow ions have little influence. The second example considers planar electrostatic probes biased near the plasma potential using model equations and particle-in-cell simulations. This demonstrates a situation where electron kinetic effects alter the Bohm criterion, leading to a subsonic ion flow at the sheath edge.