Microstructure Evolution and Mechanical Properties of a SMATed Mg Alloy under In Situ SEM Tensile Testing

Surface mechanical attrition treatment(SMAT) has been recently applied to bulk polycrystalline magnesium(Mg) alloys with gradient grain size distribution from the impact surface to inside matrix, hence effectively improving the alloys' mechanical performances. However, in-depth understanding of thei...

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Bibliographic Details
Published inJournal of materials science & technology Vol. 33; no. 3; pp. 224 - 230
Main Authors Liu, Xiaowei, Liu, Yong, Jin, Bin, Lu, Yang, Lu, Jian
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.03.2017
Subjects
AZ31镁合金
In situ SEM
Mechanical property
Mg alloy
Microstructure characterization
Surface mechanical attrition treatment (SMAT)
力学性能
原位
合金样品
微观结构
扫描电子显微镜
拉伸试验
表面机械研磨处理
Microstructure characterization
Mg alloy
Surface mechanical attrition treatment (SMAT)
Mechanical property
In situ SEM
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Summary:Surface mechanical attrition treatment(SMAT) has been recently applied to bulk polycrystalline magnesium(Mg) alloys with gradient grain size distribution from the impact surface to inside matrix, hence effectively improving the alloys' mechanical performances. However, in-depth understanding of their mechanical property enhancement and grain size-dependent fracture mechanism remains unclear. Here,we demonstrated the use of in situ micro-tensile testing inside a high resolution scanning electron microscope(SEM) to characterize the microstructure evolution, in real time, of SMATed Mg alloy AZ31 samples with different grain sizes of ~10 μm('coarse-grain sample') and ~5 μm('fine-grain sample'), respectively, and compared the results with those of a raw Mg alloy AZ31. The quantitative tensile tests with in situ SEM imaging clearly showed that fracture of ‘fine-grain sample' was dominated by intergranular cracks,while both trans-granular and intergranular cracks led to the final failure of the ‘coarse-grain samples'.It is expected that this in situ SEM characterization technique, coupled with quantitative tensile testing method, could be applicable for studying other grain-refined metals/alloys, allowing to optimize their mechanical performances by controlling the grain sizes and their gradient distribution.
Bibliography:21-1315/TG
Surface mechanical attrition treatment(SMAT) Mg alloy Mechanical property In situ SEM Microstructure characterization
Surface mechanical attrition treatment(SMAT) has been recently applied to bulk polycrystalline magnesium(Mg) alloys with gradient grain size distribution from the impact surface to inside matrix, hence effectively improving the alloys' mechanical performances. However, in-depth understanding of their mechanical property enhancement and grain size-dependent fracture mechanism remains unclear. Here,we demonstrated the use of in situ micro-tensile testing inside a high resolution scanning electron microscope(SEM) to characterize the microstructure evolution, in real time, of SMATed Mg alloy AZ31 samples with different grain sizes of ~10 μm('coarse-grain sample') and ~5 μm('fine-grain sample'), respectively, and compared the results with those of a raw Mg alloy AZ31. The quantitative tensile tests with in situ SEM imaging clearly showed that fracture of ‘fine-grain sample' was dominated by intergranular cracks,while both trans-granular and intergranular cracks led to the final failure of the ‘coarse-grain samples'.It is expected that this in situ SEM characterization technique, coupled with quantitative tensile testing method, could be applicable for studying other grain-refined metals/alloys, allowing to optimize their mechanical performances by controlling the grain sizes and their gradient distribution.
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2016.11.012