The Interaction between He Bubble and Migrating Grain Boundary Induced by Shear Loading

Qi Zhu; Jianli Shao; Pei Wang

doi:10.3390/met12122012

The Interaction between He Bubble and Migrating Grain Boundary Induced by Shear Loading

Qi Zhu, Jianli Shao^*, Pei Wang^*

^*Corresponding author for this work

School of Mechatronical Engineering

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

3 Citations (Scopus)

Abstract

This work reveals the interaction mechanism between He bubble and grain boundary (GB) in bicrystal copper under shear loading via molecular dynamics simulations. The influences of He/vacancy ratio R_He/V, temperature T₀, and bubble diameter D₀ on the interaction mechanism are clarified. Specifically, two interaction modes, i.e., the GB traverses or is pinned on He bubble, are observed by changing the initial R_He/V, T₀, and D₀. As R_He/V increases, the influence of He bubble on GB migration shows a decrease–increase trend. Different He bubble evolutions are demonstrated by comparing their shapes, pressure, and volume. In the cases of low R_He/V, the medium temperatures (10–300 K) are found to accelerate the GB migration, but higher temperatures (600–900 K) will lead to the change in interaction mode and deteriorate the interaction process. Furthermore, a more noticeable bubble-drag effect on GB migration is observed in the samples with larger He bubble.

Original language	English
Article number	2012
Journal	Metals
Volume	12
Issue number	12
DOIs	https://doi.org/10.3390/met12122012
Publication status	Published - Dec 2022

Keywords

He bubble
grain boundary
molecular dynamics
shear-coupled motion

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10.3390/met12122012

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title = "The Interaction between He Bubble and Migrating Grain Boundary Induced by Shear Loading",

abstract = "This work reveals the interaction mechanism between He bubble and grain boundary (GB) in bicrystal copper under shear loading via molecular dynamics simulations. The influences of He/vacancy ratio RHe/V, temperature T0, and bubble diameter D0 on the interaction mechanism are clarified. Specifically, two interaction modes, i.e., the GB traverses or is pinned on He bubble, are observed by changing the initial RHe/V, T0, and D0. As RHe/V increases, the influence of He bubble on GB migration shows a decrease–increase trend. Different He bubble evolutions are demonstrated by comparing their shapes, pressure, and volume. In the cases of low RHe/V, the medium temperatures (10–300 K) are found to accelerate the GB migration, but higher temperatures (600–900 K) will lead to the change in interaction mode and deteriorate the interaction process. Furthermore, a more noticeable bubble-drag effect on GB migration is observed in the samples with larger He bubble.",

keywords = "He bubble, grain boundary, molecular dynamics, shear-coupled motion",

author = "Qi Zhu and Jianli Shao and Pei Wang",

note = "Publisher Copyright: {\textcopyright} 2022 by the authors.",

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doi = "10.3390/met12122012",

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journal = "Metals",

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T1 - The Interaction between He Bubble and Migrating Grain Boundary Induced by Shear Loading

AU - Zhu, Qi

AU - Shao, Jianli

AU - Wang, Pei

PY - 2022/12

Y1 - 2022/12

N2 - This work reveals the interaction mechanism between He bubble and grain boundary (GB) in bicrystal copper under shear loading via molecular dynamics simulations. The influences of He/vacancy ratio RHe/V, temperature T0, and bubble diameter D0 on the interaction mechanism are clarified. Specifically, two interaction modes, i.e., the GB traverses or is pinned on He bubble, are observed by changing the initial RHe/V, T0, and D0. As RHe/V increases, the influence of He bubble on GB migration shows a decrease–increase trend. Different He bubble evolutions are demonstrated by comparing their shapes, pressure, and volume. In the cases of low RHe/V, the medium temperatures (10–300 K) are found to accelerate the GB migration, but higher temperatures (600–900 K) will lead to the change in interaction mode and deteriorate the interaction process. Furthermore, a more noticeable bubble-drag effect on GB migration is observed in the samples with larger He bubble.

AB - This work reveals the interaction mechanism between He bubble and grain boundary (GB) in bicrystal copper under shear loading via molecular dynamics simulations. The influences of He/vacancy ratio RHe/V, temperature T0, and bubble diameter D0 on the interaction mechanism are clarified. Specifically, two interaction modes, i.e., the GB traverses or is pinned on He bubble, are observed by changing the initial RHe/V, T0, and D0. As RHe/V increases, the influence of He bubble on GB migration shows a decrease–increase trend. Different He bubble evolutions are demonstrated by comparing their shapes, pressure, and volume. In the cases of low RHe/V, the medium temperatures (10–300 K) are found to accelerate the GB migration, but higher temperatures (600–900 K) will lead to the change in interaction mode and deteriorate the interaction process. Furthermore, a more noticeable bubble-drag effect on GB migration is observed in the samples with larger He bubble.

KW - He bubble

KW - grain boundary

KW - molecular dynamics

KW - shear-coupled motion

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JO - Metals

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ER -

The Interaction between He Bubble and Migrating Grain Boundary Induced by Shear Loading

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Keywords

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