Towards an integrated modeling of the plasma-solid interface

TL;DR

This paper discusses the need for integrated plasma-solid interface modeling, reviewing theoretical methods like KMC, MD, quantum Boltzmann, DFT, and Green functions to improve understanding and predictive capabilities.

Contribution

It identifies and compares four key theoretical approaches for coupled plasma-solid interface simulations, highlighting their roles and limitations.

Findings

Current models often neglect plasma effects on surfaces.

Four theoretical methods are suitable for integrated modeling.

A comprehensive approach can improve predictive power.

Abstract

Solids facing a plasma are a common situation in many astrophysical systems and laboratory setups. Moreover, many plasma technology applications rely on the control of the plasma-surface interaction. However, presently often a fundamental understanding of them is missing, so most technological applications are being developed via trial and error. In the majority of plasma simulations surface processes are either neglected or treated via phenomenological parameters such as sticking coefficients, sputter rates or secondary electron emission coefficients. However, those parameters are known only in some cases and with very limited accuracy. Similarly, while surface physics simulations have often studied the impact of single ions or neutrals, so far, the influence of a plasma medium and correlations between successive impacts have not been taken into account. Such an approach cannot have predictive power. In this paper we discuss in some detail the physical processes a the plasma-solid interface which brings us to the necessity of coupled plasma-solid simulations. We briefly summarize relevant theoretical methods from solid state and surface physics that are suitable to contribute to such an approach and identify four methods. The first are mesoscopic simulations such as kinetic Monte Carlo (KMC) and molecular dynamics (MD) that are able to treat complex processes on large scales but neglect electronic effects. The second are quantum kinetic methods based on the quantum Boltzmann equation that give access to a more accurate treatment of surface processes using simplifying models for the solid. The third approach are ab initio simulations of surface process that are based on density functional theory (DFT) and time-dependent DFT. The fourths are nonequilibrium Green functions that able to treat correlation effects in the material and at the interface.