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RustBCA: A High-Performance Binary-Collision-Approximation Code for Ion-Material Interactions

Jon Drobny, Davide Curreli

2021The Journal of Open Source Software31 citationsDOIOpen Access PDF

Abstract

Ion-material interactions are of vital importance in industrial applications, the study and design of nuclear fusion devices, the engineering of survivable spacecraft components, and more. In particular, plasma-material interactions are typically dominated by ion-material interactions, including the phenomena of sputtering, reflection, and implantation. These phenomena are difficult to model analytically, and many such models rely on empirical or semi-empirical formulas, such as the Yamamura sputtering yield formula (Y. However, such models are inherently limited, and of little applicability to complex geometry, multi-component surfaces, or for coupling to plasma or material dynamics codes. Since ion-material interactions span a range of energies from sub-eV to GeV and beyond, n-body approaches such as molecular dynamics can be computationally infeasible for many applications where the characteristic ion range exceeds the limits of reasonable molecular dynamics domains. Instead, approximations to the full n-body problem are used; the most common of these is the Binary Collision Approximation (BCA), a set of simplifying assumptions to the full n-body problem. RustBCA is a high-performance, general purpose, ion-material interactions BCA code, built for scientific flexibility and ease of use. RustBCA features include:

Topics & Concepts

CollisionBinary numberCode (set theory)IonComputer scienceMaterials scienceParallel computingPhysicsMathematicsProgramming languageArithmeticQuantum mechanicsSet (abstract data type)Ion-surface interactions and analysisMass Spectrometry Techniques and ApplicationsAnalytical chemistry methods development
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