Irradiation-induced creep in nanocrystalline Cu alloys

Noya Dimanstein Firman; Eliyahu Zvi Engelberg; Yinon Ashkenazy

doi:10.1016/j.commatsci.2025.113886

Irradiation-induced creep in nanocrystalline Cu alloys

Noya Dimanstein Firman^*
, Eliyahu Zvi Engelberg
, Yinon Ashkenazy

^*Corresponding author for this work

Racah Institute of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Irradiation-induced creep in nanocrystalline Cu was simulated with the aim of analyzing the microscopic mechanism driving creep. The systems included various immiscible mixtures where the solute atom segregated at grain boundaries and led to grain size stabilization. The small grain size in the nanocrystals prevents the development of dislocation-based dynamics within the grains, and gives rise to alternative mechanisms that are based on grain-boundary plasticity. We show a correlation between observed creep rates and the climbing of dislocations at the grain boundaries. Due to the simple structure of Cu-based alloys, they can serve as model systems for investigating irradiation-induced creep. This establishes the basis for a mean-field model that can predict the creep compliance of a sample as a function of its structure and composition. The model reproduces recent experimental measurements.

Original language	English
Article number	113886
Journal	Computational Materials Science
Volume	255
DOIs	https://doi.org/10.1016/j.commatsci.2025.113886
State	Published - 5 Jun 2025

Bibliographical note

Publisher Copyright:
© 2025 The Authors

Keywords

Copper alloys
Grain boundary defects
Irradiation-induced creep (IIC)
Molecular dynamics (MD)
Nanocrystalline metal

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10.1016/j.commatsci.2025.113886

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title = "Irradiation-induced creep in nanocrystalline Cu alloys",

abstract = "Irradiation-induced creep in nanocrystalline Cu was simulated with the aim of analyzing the microscopic mechanism driving creep. The systems included various immiscible mixtures where the solute atom segregated at grain boundaries and led to grain size stabilization. The small grain size in the nanocrystals prevents the development of dislocation-based dynamics within the grains, and gives rise to alternative mechanisms that are based on grain-boundary plasticity. We show a correlation between observed creep rates and the climbing of dislocations at the grain boundaries. Due to the simple structure of Cu-based alloys, they can serve as model systems for investigating irradiation-induced creep. This establishes the basis for a mean-field model that can predict the creep compliance of a sample as a function of its structure and composition. The model reproduces recent experimental measurements.",

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AU - Firman, Noya Dimanstein

AU - Engelberg, Eliyahu Zvi

AU - Ashkenazy, Yinon

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N2 - Irradiation-induced creep in nanocrystalline Cu was simulated with the aim of analyzing the microscopic mechanism driving creep. The systems included various immiscible mixtures where the solute atom segregated at grain boundaries and led to grain size stabilization. The small grain size in the nanocrystals prevents the development of dislocation-based dynamics within the grains, and gives rise to alternative mechanisms that are based on grain-boundary plasticity. We show a correlation between observed creep rates and the climbing of dislocations at the grain boundaries. Due to the simple structure of Cu-based alloys, they can serve as model systems for investigating irradiation-induced creep. This establishes the basis for a mean-field model that can predict the creep compliance of a sample as a function of its structure and composition. The model reproduces recent experimental measurements.

AB - Irradiation-induced creep in nanocrystalline Cu was simulated with the aim of analyzing the microscopic mechanism driving creep. The systems included various immiscible mixtures where the solute atom segregated at grain boundaries and led to grain size stabilization. The small grain size in the nanocrystals prevents the development of dislocation-based dynamics within the grains, and gives rise to alternative mechanisms that are based on grain-boundary plasticity. We show a correlation between observed creep rates and the climbing of dislocations at the grain boundaries. Due to the simple structure of Cu-based alloys, they can serve as model systems for investigating irradiation-induced creep. This establishes the basis for a mean-field model that can predict the creep compliance of a sample as a function of its structure and composition. The model reproduces recent experimental measurements.

KW - Copper alloys

KW - Grain boundary defects

KW - Irradiation-induced creep (IIC)

KW - Molecular dynamics (MD)

KW - Nanocrystalline metal

UR - https://www.scopus.com/pages/publications/105003302332

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VL - 255

JO - Computational Materials Science

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Irradiation-induced creep in nanocrystalline Cu alloys

Abstract

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Keywords

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