Stabilizing a severely deformed Al-7Mg alloy with a multimodal grain structure via Mg solute segregation

Min Zha ¹Hong-Min Zhang ²Xiang-Tao Meng ²Hai-Long Jia ³Shen-Bao Jin ⁴Gang Sha ⁴Hui-Yuan Wang ¹Yan-Jun Li ⁵Hans J.Roven⁵

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作者信息

1. State Key Laboratory of Superhard Materials,Jilin University,Changchun,130012,China;Key Laboratory of Automobile Materials of Ministry of Education &School of Materials Science and Engineering,Nanling Campus,Jilin University,Changchun,130025,China;International Center of Future Science,Jilin University,Changchun,130012,China
2. Key Laboratory of Automobile Materials of Ministry of Education &School of Materials Science and Engineering,Nanling Campus,Jilin University,Changchun,130025,China
3. Key Laboratory of Automobile Materials of Ministry of Education &School of Materials Science and Engineering,Nanling Campus,Jilin University,Changchun,130025,China;International Center of Future Science,Jilin University,Changchun,130012,China
4. Department of Materials Science and Engineering,Nanjing University of Science and Technology,Nanjing.210094,China
5. Department of Materials Science and Engineering,Norwegian University of Science and Technology,7491,Trondheim,Norway
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Abstract

Single-phase Al-Mg alloys processed by severe plastic deformation (SPD) usually suffer from unsatis-factory thermal stability at moderate to high temperatures with recrystallization occurring and obvious grain coarsening.In the present work,an Al-7Mg alloy prepared by equal-channel angular pressing(ECAP) possessed markedly enhanced thermal stability upon annealing at moderate to high temperatures(200-275 ℃),compared with those ultrafine-grained dilute Al-Mg alloys with a uniform microstructure.The enhanced thermal stability is due primarily to the multimodal grain structure consisting of nano-,ultrafine-and micron-sized grains,strong segregation and/or clusters of Mg solute along grain bound-aries (GBs),and Al3Mg2 precipitates formed during annealing.First,extensive recovery predominates over recrystallization and consumes most of the stored energy in the ECAPed Al-7Mg alloy annealed at≤ 275 ℃,leading to the recrystallization and growth of nano/ultrafine grains being retarded or post-poned.Moreover,Mg solute segregation and/or clusters along GBs of nano/ultrafine grains could further suppress grain growth via diminishing GB energy and dragging GBs efficiently.In addition,Al3Mg2 pre-cipitates formed with increasing annealing time could inhibit grain growth by pinning GBs.The present multimodal-grained Al-7Mg alloy with enhanced thermal stability is believed to be particularly attractive in potential engineering applications at moderate to high temperatures.

Key words

Al-Mg alloys/ECAP/Multimodal grain structure/Solute segregation/Thermal stability

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基金项目

National Natural Science Foundation of China(51922048)

National Natural Science Foundation of China(51790483)

National Natural Science Foundation of China(51871108)

Changjiang Scholars Program(T2017035)

出版年

2021

材料科学技术(英文版)

中国金属学会中国材料研究学会中国科学院金属研究所

材料科学技术(英文版)

CSTPCDCSCDSCI

影响因子：0.657

ISSN：1005-0302

参考文献量46

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