Ion-beam radiation-induced Eshelby transformations: The mean and variance in hydrostatic and shear residual stresses

Ion beam plays a pivotal role in ion implantations and the fabrication of nanostructures. However, there lacks a quantitative model to describe the residual stresses associated with the ion-beam radiation. Radiation-induced residual stress/transformation strain have been mostly recognized in the hyd...

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Bibliographic Details
Published in:Extreme Mechanics Letters 2023-03, Vol.59 (C), p.101970, Article 101970
Main Authors: Chen, Yongchao, Li, Qing-Jie, O’Brien, Alexander D., Yang, Yang, He, Qi, Bloore, David A., Vlassak, Joost J., Li, Ju
Format: Article
Language:English
Subjects:
Generalized radiation creep
Generalized radiation swelling
Ion/electron beam fabrication
Radiation
Residual stress
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Summary:Ion beam plays a pivotal role in ion implantations and the fabrication of nanostructures. However, there lacks a quantitative model to describe the residual stresses associated with the ion-beam radiation. Radiation-induced residual stress/transformation strain have been mostly recognized in the hydrostatic sub strain space. Here, we use molecular dynamics (MD) simulations to show that the response of a material to irradiation is generally anisotropic that depends on the ion-beam direction, and should be described using tensorial quantities. We demonstrate that accelerator-based ion beam irradiation, combined with the intrinsic lattice anisotropy and externally induced anisotropy (such as anisotropic mechanical loadings), causes radiation-actuated shear transformation strains in addition to hydrostatic expansion. We map out these complex correlations for several materials. Radiation-induced defects are shown to be responsible for residual shear stresses in the manner of Eshelby inclusion transformation. We propose such tensorial response model should be considered for accurate nanoscale fabrication using ion-beam irradiation. [Display omitted]
ISSN:2352-4316
2352-4316
DOI:10.1016/j.eml.2023.101970