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Main Authors: Wilczynski, Maciej, Fedorov, Mark, Khvan, Tymofii, Dominguez-Gutierrez, F. Javier, Jagielski, and Jacek
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.24343
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author Wilczynski, Maciej
Fedorov, Mark
Khvan, Tymofii
Dominguez-Gutierrez, F. Javier
Jagielski, and Jacek
author_facet Wilczynski, Maciej
Fedorov, Mark
Khvan, Tymofii
Dominguez-Gutierrez, F. Javier
Jagielski, and Jacek
contents Molecular dynamics (MD) simulations were performed to investigate the influence of mechanical strain on irradiation-induced defect and dislocation evolution in nickel single crystals subjected to cumulative overlapping 5 keV collision cascades at 300 K. The simulations reveal that tensile strain modifies the dynamics of defect generation and recovery, promoting stress-assisted defect mobility and enhancing defect survival compared to the unstrained case. The heat spike duration and intensity decrease systematically with increasing strain, indicating faster energy dissipation and altered defect recombination behavior under applied stress. Analysis of the dislocation structure shows that Shockley-type partial dislocations dominate the microstructural response, while Hirth and other dislocation types remain comparatively minor. Both the total and Shockley dislocation densities reach a saturation value of $~10^{16}m^{-2}$ , marking the establishment of a steady-state microstructure governed by the balance between dislocation accumulation and recovery. The evolution of the total dislocation density with strain is successfully described by the Kocks-Mecking model, demonstrating its applicability to strain-dependent irradiation effects in metallic systems
format Preprint
id arxiv_https___arxiv_org_abs_2510_24343
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Molecular Dynamics Study of Irradiation-Induced Defect and Dislocation Evolution in Strained Nickel
Wilczynski, Maciej
Fedorov, Mark
Khvan, Tymofii
Dominguez-Gutierrez, F. Javier
Jagielski, and Jacek
Materials Science
Molecular dynamics (MD) simulations were performed to investigate the influence of mechanical strain on irradiation-induced defect and dislocation evolution in nickel single crystals subjected to cumulative overlapping 5 keV collision cascades at 300 K. The simulations reveal that tensile strain modifies the dynamics of defect generation and recovery, promoting stress-assisted defect mobility and enhancing defect survival compared to the unstrained case. The heat spike duration and intensity decrease systematically with increasing strain, indicating faster energy dissipation and altered defect recombination behavior under applied stress. Analysis of the dislocation structure shows that Shockley-type partial dislocations dominate the microstructural response, while Hirth and other dislocation types remain comparatively minor. Both the total and Shockley dislocation densities reach a saturation value of $~10^{16}m^{-2}$ , marking the establishment of a steady-state microstructure governed by the balance between dislocation accumulation and recovery. The evolution of the total dislocation density with strain is successfully described by the Kocks-Mecking model, demonstrating its applicability to strain-dependent irradiation effects in metallic systems
title Molecular Dynamics Study of Irradiation-Induced Defect and Dislocation Evolution in Strained Nickel
topic Materials Science
url https://arxiv.org/abs/2510.24343