Microstructure evolution and mechanical behavior of the Ni/Ni3Al interface under thermal-mechanical coupling

Jingui Yu; Qiaoxin Zhang; Zhufeng Yue; Rong Liu; Mingkai Tang; Xuewu Li

doi:10.1166/mex.2015.1238

Microstructure evolution and mechanical behavior of the Ni/Ni₃Al interface under thermal-mechanical coupling

Jingui Yu, Qiaoxin Zhang, Zhufeng Yue, Rong Liu, Mingkai Tang, Xuewu Li

力学与土木建筑学院

Wuhan University of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

9 引用（Scopus）

摘要

Molecular dynamics (MD) simulations are used to understand the microstructure evolution and mechanical behavior of the Ni/Ni₃Al interface under thermal-mechanical coupling. The results indicate that the shapes of dislocation networks of the laminated model and the sandwich model are the symmetrical π-shaped and the symmetrical double-deck π-shaped respectively. We find that the rod dislocation only exists in the sandwich model. The critical shear stress of laminated model is larger than the sandwich model’s. The stress and potential energy of dislocation network are larger than other places in the Ni/Ni₃Al interface. Moreover, slip systems of the laminated model and the sandwich model are {111}(101), {11.1}(011), {1.11}(. 101) and {111}(0.11).

源语言	英语
页（从-至）	343-350
页数	8
期刊	Materials Express
卷	5
期	4
DOI	https://doi.org/10.1166/mex.2015.1238
出版状态	已出版 - 1 8月 2015

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10.1166/mex.2015.1238

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title = "Microstructure evolution and mechanical behavior of the Ni/Ni3Al interface under thermal-mechanical coupling",

abstract = "Molecular dynamics (MD) simulations are used to understand the microstructure evolution and mechanical behavior of the Ni/Ni3Al interface under thermal-mechanical coupling. The results indicate that the shapes of dislocation networks of the laminated model and the sandwich model are the symmetrical π-shaped and the symmetrical double-deck π-shaped respectively. We find that the rod dislocation only exists in the sandwich model. The critical shear stress of laminated model is larger than the sandwich model{\textquoteright}s. The stress and potential energy of dislocation network are larger than other places in the Ni/Ni3Al interface. Moreover, slip systems of the laminated model and the sandwich model are {111}(101), {11.1}(011), {1.11}(. 101) and {111}(0.11).",

keywords = "Microstructure evolution, Molecular dynamics, Ni/NiAl interface, Thermal-mechanical coupling",

author = "Jingui Yu and Qiaoxin Zhang and Zhufeng Yue and Rong Liu and Mingkai Tang and Xuewu Li",

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AU - Yu, Jingui

AU - Zhang, Qiaoxin

AU - Yue, Zhufeng

AU - Liu, Rong

AU - Tang, Mingkai

AU - Li, Xuewu

PY - 2015/8/1

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N2 - Molecular dynamics (MD) simulations are used to understand the microstructure evolution and mechanical behavior of the Ni/Ni3Al interface under thermal-mechanical coupling. The results indicate that the shapes of dislocation networks of the laminated model and the sandwich model are the symmetrical π-shaped and the symmetrical double-deck π-shaped respectively. We find that the rod dislocation only exists in the sandwich model. The critical shear stress of laminated model is larger than the sandwich model’s. The stress and potential energy of dislocation network are larger than other places in the Ni/Ni3Al interface. Moreover, slip systems of the laminated model and the sandwich model are {111}(101), {11.1}(011), {1.11}(. 101) and {111}(0.11).

AB - Molecular dynamics (MD) simulations are used to understand the microstructure evolution and mechanical behavior of the Ni/Ni3Al interface under thermal-mechanical coupling. The results indicate that the shapes of dislocation networks of the laminated model and the sandwich model are the symmetrical π-shaped and the symmetrical double-deck π-shaped respectively. We find that the rod dislocation only exists in the sandwich model. The critical shear stress of laminated model is larger than the sandwich model’s. The stress and potential energy of dislocation network are larger than other places in the Ni/Ni3Al interface. Moreover, slip systems of the laminated model and the sandwich model are {111}(101), {11.1}(011), {1.11}(. 101) and {111}(0.11).

KW - Microstructure evolution

KW - Molecular dynamics

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KW - Thermal-mechanical coupling

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Microstructure evolution and mechanical behavior of the Ni/Ni3Al interface under thermal-mechanical coupling

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Microstructure evolution and mechanical behavior of the Ni/Ni₃Al interface under thermal-mechanical coupling