Microstructure and strengthening mechanisms of Mg-6Al-6Nd alloy 被引量：3

Microstructure and strengthening mechanisms of Mg-6Al-6Nd alloy

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摘要 The microstructure and strengthening mechanisms of as-cast Mg-6Al-6Nd alloy were studied. The results show that the addition of 6 wt.% Nd into Mg-6Al alloy leads to the precipitation of Al11Nd3 and Al2Nd phases and decrease in the content of Al solid soluted in Mg-Al matrix. The volume fractions of Al11Nd3 and Al2Nd phases are 3.64% and 0.34%, respectively. Compared with Mg-6Al alloy, the ultimate strength, yielding strength, and elongation of Mg-6Al-6Nd alloy at room temperature and 175℃ are enhanced in some degrees. The strengthening mechanisms of Mg-6Al-6Nd alloy are mainly composed of solid solution strengthening of Al solid soluted in Mg-Al matrix and grain refmement strengthening, dispersion strengthening, and composite strengthening brought by the precipitation of Al11Nd3 phase. The composite strengthening includes the load transfer from the matrix to Al11Nd3 phase and the enhancement of dislocation density due to the geometrical mismatch and thermal mismatch between the matrix and Al11Nd3 phase. The microstructure and strengthening mechanisms of as-cast Mg-6Al-6Nd alloy were studied. The results show that the addition of 6 wt.% Nd into Mg-6Al alloy leads to the precipitation of Al11Nd3 and Al2Nd phases and decrease in the content of Al solid soluted in Mg-Al matrix. The volume fractions of Al11Nd3 and Al2Nd phases are 3.64% and 0.34%, respectively. Compared with Mg-6Al alloy, the ultimate strength, yielding strength, and elongation of Mg-6Al-6Nd alloy at room temperature and 175℃ are enhanced in some degrees. The strengthening mechanisms of Mg-6Al-6Nd alloy are mainly composed of solid solution strengthening of Al solid soluted in Mg-Al matrix and grain refmement strengthening, dispersion strengthening, and composite strengthening brought by the precipitation of Al11Nd3 phase. The composite strengthening includes the load transfer from the matrix to Al11Nd3 phase and the enhancement of dislocation density due to the geometrical mismatch and thermal mismatch between the matrix and Al11Nd3 phase.

作者 WU Yufeng DU Wenbo YAN Zhenjie WANG Zhaohui ZUO Tieyong

机构地区 Institute of Recycling Economy College of Materials Science and Engineering

出处《Rare Metals》 SCIE EI CAS CSCD 2010年第1期55-61,共7页 稀有金属（英文版）

基金 supported by the Major State Basic Research Development Program of China (No.2007CB613706) the Project of Key Disciplines Development "Resources, Environment and Recycling Economy" Interdisciplinary under the Jurisdiction of Beijing Municipality (No.0330005412901) the Project Sponsored by the Scientific Research Foundation for Doctoral Teachers, Beijing University of Technology (No.X0104001200905)

关键词 magnesium alloys strengthening mechanism quantitative analysis PRECIPITATION magnesium alloys strengthening mechanism quantitative analysis precipitation

分类号 TG139.7 [一般工业技术—材料科学与工程] TB333 [一般工业技术—材料科学与工程]

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Microstructure and strengthening mechanisms of Mg-6Al-6Nd alloy 被引量：3

参考文献15

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