| Controlling Σ3n Grain Boundary Distribution in GH3625 Alloy | |
| Gao, Yubi; Ding, Yutian; Chen, Jianjun; Xu, Jiayu; Ma, Yuanjun; Wang, Xingmao | |
| 刊名 | Xiyou Jinshu/Chinese Journal of Rare Metals
 |
| 2020-07-01 | |
| 卷号 | 44期号:7页码:673-679 |
| 关键词 | Annealing Crystal lattices Deformation Microstructure Twinning Annealing treatments Coincidence site lattice grain boundaries Coincidence site lattices Electron back scatter diffraction Grain boundary distribution Grain boundary types Orientation imaging microscopy Recrystallization-annealing |
| ISSN号 | 02587076 |
| DOI | 10.13373/j.cnki.cjrm.XY18120011 |
| 英文摘要 | The grain boundary types of GH3625 alloy after cold deformation and annealing treatment were studied by electron backscatter diffraction (EBSD) and orientation imaging microscopy (OIM). And the mechanism of grain boundary distribution based on Σ3n (n=1, 2, 3) grain boundary was discussed. The results showed that the proportion of deformation twin boundary and low tantalum coincidence site lattice (CSL) grain boundary in GH3625 alloy increased gradually with the increase of cold deformation, but its proportion accounted for less than 5% of the whole grain boundary, which was not enough to control the alloy grain boundary character distribution, during cold deformation process. During the annealing process, the proportion of low ΣCSL grain boundary in GH3625 alloy decreased with the increase of cold deformation before annealing. When the cold deformation was 35% (the compression strain), annealing at 1100 °C for 10 min could make the proportion of low ΣCSL (coincidence site lattice, 1n grain boundaries accounted for more than 90% of the low ΣCSL grain boundaries, and simultaneously the large-sized highly-twinned grain-cluster microstructure was formed. The microstructure consisted of Σ3-Σ3-Σ9 or Σ3-Σ9-Σ27 trigeminal grain boundaries. In addition, the size of grain-cluster decreased with the increase of pre-strain. So it was concluded that the controlling of grain boundary distribution of GH3625 alloy was mainly achieved through the Σ3n grain boundary formed during recrystallization annealing rather than through the cold deformation. © Editorial Office of Chinese Journal of Rare Metals. All right reserved. |
| 语种 | 中文 |
| 出版者 | Editorial Office of Chinese Journal of Rare Metals |
| 内容类型 | 期刊论文 |
| 源URL | [http://ir.lut.edu.cn/handle/2XXMBERH/150670]  |
| 专题 | 省部共建有色金属先进加工与再利用国家重点实验室 |
| 作者单位 | State Key Laboratory of Advanced Processing and Recycling of Non-ferrous Metals, Lanzhou University of Technology, Lanzhou; 730050, China |
| 推荐引用方式 GB/T 7714 | Gao, Yubi,Ding, Yutian,Chen, Jianjun,et al. Controlling Σ3n Grain Boundary Distribution in GH3625 Alloy[J]. Xiyou Jinshu/Chinese Journal of Rare Metals,2020,44(7):673-679. |
| APA | Gao, Yubi,Ding, Yutian,Chen, Jianjun,Xu, Jiayu,Ma, Yuanjun,&Wang, Xingmao.(2020).Controlling Σ3n Grain Boundary Distribution in GH3625 Alloy.Xiyou Jinshu/Chinese Journal of Rare Metals,44(7),673-679. |
| MLA | Gao, Yubi,et al."Controlling Σ3n Grain Boundary Distribution in GH3625 Alloy".Xiyou Jinshu/Chinese Journal of Rare Metals 44.7(2020):673-679. |
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