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Main Authors: Johnson, Landon, Malone, Walter, Rizk, Jason, Chen, Renai, Gibson, Tammie, Cooper, Michael W. D., Craven, Galen T.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.17634
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author Johnson, Landon
Malone, Walter
Rizk, Jason
Chen, Renai
Gibson, Tammie
Cooper, Michael W. D.
Craven, Galen T.
author_facet Johnson, Landon
Malone, Walter
Rizk, Jason
Chen, Renai
Gibson, Tammie
Cooper, Michael W. D.
Craven, Galen T.
contents The formation and subsequent growth of structural defects in an irradiated material can strongly influence the material's performance in technological and industrial applications. Predicting how the growth of defects affects material performance is therefore a pressing problem in materials science. One common computational approach that is used to examine defect growth is cluster dynamics, a method which employs a system of mean-field rate equations to track the time evolution of concentrations of individual defect types. However, the computational complexity of performing cluster dynamics can limit its practical implementation, specifically in the context of exploring a broad set of physical conditions corresponding to, for example, different temperatures and pressures. Here, we present a machine learning approach to circumvent the computational challenges of performing cluster dynamics while maintaining high accuracy in the prediction of defect concentrations. The method is illustrated on the nuclear material uranium nitride but is broadly applicable to other materials. The developed data-driven method is shown to accurately capture complex correlations between material properties, temperature, irradiation conditions, and the concentration of defects.
format Preprint
id arxiv_https___arxiv_org_abs_2510_17634
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine learning method to determine concentrations of structural defects in irradiated materials
Johnson, Landon
Malone, Walter
Rizk, Jason
Chen, Renai
Gibson, Tammie
Cooper, Michael W. D.
Craven, Galen T.
Materials Science
The formation and subsequent growth of structural defects in an irradiated material can strongly influence the material's performance in technological and industrial applications. Predicting how the growth of defects affects material performance is therefore a pressing problem in materials science. One common computational approach that is used to examine defect growth is cluster dynamics, a method which employs a system of mean-field rate equations to track the time evolution of concentrations of individual defect types. However, the computational complexity of performing cluster dynamics can limit its practical implementation, specifically in the context of exploring a broad set of physical conditions corresponding to, for example, different temperatures and pressures. Here, we present a machine learning approach to circumvent the computational challenges of performing cluster dynamics while maintaining high accuracy in the prediction of defect concentrations. The method is illustrated on the nuclear material uranium nitride but is broadly applicable to other materials. The developed data-driven method is shown to accurately capture complex correlations between material properties, temperature, irradiation conditions, and the concentration of defects.
title Machine learning method to determine concentrations of structural defects in irradiated materials
topic Materials Science
url https://arxiv.org/abs/2510.17634