Microscopic phase-field simulation of antisite defect evolution of Al3Li phase

Liyan Sun; Zheng Chen; Yongxin Wang; Jing Zhang; Haichuan Miao; Hanwen Zhong

Microscopic phase-field simulation of antisite defect evolution of Al₃Li phase

Liyan Sun, Zheng Chen, Yongxin Wang, Jing Zhang, Haichuan Miao, Hanwen Zhong

Queen Mary University of London Engineering School

Northwestern Polytechnical University Xian

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

7 Scopus citations

Abstract

Based on the microscopic phase-field dynamic diffusion equation (the Langevin equation), the effects of concentration and temperature on the antisite defect evolution in Al₃Li phase are investigated. The results show that the main antisite defect in Al₃Li phase is AlLi, in which the Li sites are taken by Al atoms; there also exists a little amount of LiAl, in which the Al sites are taken by Li atoms. The two antisite defects are all increase with the increase of temperature, and the rising rate for AlLi is far larger than for LiAl. With the increase of Li concentration, the AlLi concentration decreases slowly and the LiAl concentration increases slightly, but still far less than the AlLi concentration. It is found that the effects of temperature on the antisite defects are more obvious than the concentration.

Original language	English
Pages (from-to)	86-89
Number of pages	4
Journal	Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering
Volume	38
Issue number	1
State	Published - Jan 2009

Keywords

AlLi phase
Antisite defect
Microscopic phase-field

Cite this

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title = "Microscopic phase-field simulation of antisite defect evolution of Al3Li phase",

abstract = "Based on the microscopic phase-field dynamic diffusion equation (the Langevin equation), the effects of concentration and temperature on the antisite defect evolution in Al3Li phase are investigated. The results show that the main antisite defect in Al3Li phase is AlLi, in which the Li sites are taken by Al atoms; there also exists a little amount of LiAl, in which the Al sites are taken by Li atoms. The two antisite defects are all increase with the increase of temperature, and the rising rate for AlLi is far larger than for LiAl. With the increase of Li concentration, the AlLi concentration decreases slowly and the LiAl concentration increases slightly, but still far less than the AlLi concentration. It is found that the effects of temperature on the antisite defects are more obvious than the concentration.",

keywords = "AlLi phase, Antisite defect, Microscopic phase-field",

author = "Liyan Sun and Zheng Chen and Yongxin Wang and Jing Zhang and Haichuan Miao and Hanwen Zhong",

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journal = "Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering",

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TY - JOUR

T1 - Microscopic phase-field simulation of antisite defect evolution of Al3Li phase

AU - Sun, Liyan

AU - Chen, Zheng

AU - Wang, Yongxin

AU - Zhang, Jing

AU - Miao, Haichuan

AU - Zhong, Hanwen

PY - 2009/1

Y1 - 2009/1

N2 - Based on the microscopic phase-field dynamic diffusion equation (the Langevin equation), the effects of concentration and temperature on the antisite defect evolution in Al3Li phase are investigated. The results show that the main antisite defect in Al3Li phase is AlLi, in which the Li sites are taken by Al atoms; there also exists a little amount of LiAl, in which the Al sites are taken by Li atoms. The two antisite defects are all increase with the increase of temperature, and the rising rate for AlLi is far larger than for LiAl. With the increase of Li concentration, the AlLi concentration decreases slowly and the LiAl concentration increases slightly, but still far less than the AlLi concentration. It is found that the effects of temperature on the antisite defects are more obvious than the concentration.

AB - Based on the microscopic phase-field dynamic diffusion equation (the Langevin equation), the effects of concentration and temperature on the antisite defect evolution in Al3Li phase are investigated. The results show that the main antisite defect in Al3Li phase is AlLi, in which the Li sites are taken by Al atoms; there also exists a little amount of LiAl, in which the Al sites are taken by Li atoms. The two antisite defects are all increase with the increase of temperature, and the rising rate for AlLi is far larger than for LiAl. With the increase of Li concentration, the AlLi concentration decreases slowly and the LiAl concentration increases slightly, but still far less than the AlLi concentration. It is found that the effects of temperature on the antisite defects are more obvious than the concentration.

KW - AlLi phase

KW - Antisite defect

KW - Microscopic phase-field

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SN - 1002-185X

VL - 38

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JO - Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering

JF - Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering

IS - 1

ER -

Microscopic phase-field simulation of antisite defect evolution of Al₃Li phase

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