Atomistic simulation of tension-compression asymmetry and its mechanism in titanium single-crystal nanopillars oriented along the [112¯0] direction | |
Ren, Junqiang1,2,3; Sun, Qiaoyan1; Xiao, Lin1; Sun, Jun1 | |
刊名 | Computational Materials Science |
2018-05-01 | |
卷号 | 147页码:272-281 |
关键词 | Dislocations (crystals) Friction Molecular dynamics Plastic deformation Single crystals Stacking faults Titanium Twinning Yield stress Atomistic simulations Compression asymmetry Elastic deformation stage Intrinsic stacking fault Molecular dynamics simulations Non-linear elastic behavior Plastic deformation mechanisms Tension-compression asymmetry |
ISSN号 | 09270256 |
DOI | 10.1016/j.commatsci.2018.02.029 |
英文摘要 | Molecular dynamics simulations were performed with a Finnis-Sinclair many-body potential to investigate the mechanical properties and deformation mechanisms under applied uniaxial tensile and compressive loads in α-titanium (Ti) single-crystal nanopillars oriented along the 〈 1 1 2¯ 0 〉 direction. The results indicate that the mechanical properties and plastic deformation mechanism display tension–compression asymmetry. The non-linear elastic behavior is attributed to the difference in friction between the neighboring atomic planes at the elastic deformation stage under push and pull loading conditions. Increasing the friction leads to hardening with compression. Decreasing the friction leads to softening with tension. Increasing the friction may also lead to higher yield stress with compression compared with tension. Perfect nanopillars are yielded via the nucleation and propagation of {1¯ 0 1 0} 〈1 2¯ 1 0 〉 dislocations on the surface and corners of the nanopillars. Prismatic slip is the dominant mode of plastic deformation in the Ti nanopillars under compressive loading. However, {1 0 1¯ 1} 〈1 0 1¯2¯〉 twinning is the dominant plastic deformation mechanism together with prismatic slip under tensile loading. Two typical intrinsic stacking faults (SFs) with different propensities exist in the nanopillars. The microstructural evolution of the SFs was also simulated. © 2018 Elsevier B.V. |
语种 | 英语 |
出版者 | Elsevier B.V., Netherlands |
内容类型 | 期刊论文 |
源URL | [http://ir.lut.edu.cn/handle/2XXMBERH/114422] |
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 | 1.State Key Laboratory for Mechanical Behaviour of Materials, Xi'an Jiaotong University, Xi'an; Shaanxi; 710049, China 2.State Key Laboratory of Advanced Processing and Recycling of Nonferrous Metals, Lanzhou University of Technology, Lanzhou; 730050, China; 3.Key Laboratory of Nonferrous Metal alloys and Processing, Ministry of Education, Lanzhou University of Technology, Lanzhou; 730050, China; |
推荐引用方式 GB/T 7714 | Ren, Junqiang,Sun, Qiaoyan,Xiao, Lin,et al. Atomistic simulation of tension-compression asymmetry and its mechanism in titanium single-crystal nanopillars oriented along the [112¯0] direction[J]. Computational Materials Science,2018,147:272-281. |
APA | Ren, Junqiang,Sun, Qiaoyan,Xiao, Lin,&Sun, Jun.(2018).Atomistic simulation of tension-compression asymmetry and its mechanism in titanium single-crystal nanopillars oriented along the [112¯0] direction.Computational Materials Science,147,272-281. |
MLA | Ren, Junqiang,et al."Atomistic simulation of tension-compression asymmetry and its mechanism in titanium single-crystal nanopillars oriented along the [112¯0] direction".Computational Materials Science 147(2018):272-281. |
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