Tensile strength of a transverse grain boundary in a single-walled carbon nanotube

IF 1.3 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS
Yaoshu Xie, Kiyou Shibata, Teruyasu Mizoguchi
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Abstract

Adding carbon nanotubes (CNTs) into ceramics is an important way to promote toughness. Crystalline defects existing in materials play a significant role in affecting both their mechanical and functional performances because they bring symmetry breaking of the periodic lattice structures. For CNTs existing in real ceramic materials, which almost appear as polycrystalline forms, the most notable defects are the grain boundaries (GBs) which consist of defect cores of dislocations. It is of engineering importance to investigate the effects of these defect cores of GBs on the strength of the polycrystalline CNTs to promote the composites’ performances. The variety of grain orientations of the polycrystalline CNTs allows the GBs to have various misorientations and different arrangements of the defect cores of dislocations at the GBs, which causes disparity in the stress fields near the GBs under an external stress condition, thus making distinguishable effects on the strength. While effective rules have been established for graphene (GP) GBs to predict the tensile strengths of GP GBs with different misorientations, the effects of misorientation and curvature on the strength of CNT GBs have yet to be reported. This work studied these effects by molecular dynamics (MD) simulation. The results illustrate that the misorientation and temperature have much more significant effects than the curvature on the strength of CNT GBs, and verified a consistent tendency of the misorientation-strength relationship of the CNT GBs with the corresponding GP GBs. The CNT GBs and their corresponding GP GBs have almost identical strengths for most of the simulated results. Notable differences between CNT and GP GBs were only found at misorientations near 0 and 30° in armchair GBs. These strength differences were attributed to the crack stabilization and structural reconstruction in CNT GBs.
单壁碳纳米管横向晶界的抗拉强度
在陶瓷中加入碳纳米管(CNTs)是提高陶瓷韧性的重要途径。材料中存在的晶体缺陷会导致周期性晶格结构的对称性破坏,从而对材料的力学性能和功能性能产生重要影响。真实陶瓷材料中的碳纳米管几乎以多晶形式存在,其中最显著的缺陷是由位错缺陷核组成的晶界缺陷。研究这些缺陷核对多晶碳纳米管强度的影响,对提高复合材料的性能具有重要的工程意义。由于多晶CNTs晶粒取向的多样性,使得石墨烯中位错缺陷核在石墨烯中具有不同的取向偏差和不同的排列方式,从而导致在外加应力条件下石墨烯附近应力场的差异,从而对强度产生不同的影响。虽然已经为石墨烯(GP) gb建立了有效的规则来预测不同取向的GP gb的拉伸强度,但取向错误和曲率对碳纳米管gb强度的影响尚未报道。本文采用分子动力学(MD)模拟方法研究了这些效应。结果表明,错取向和温度对碳纳米管GBs强度的影响远大于曲率,验证了碳纳米管GBs的错取向-强度关系与相应的GP GBs具有一致的趋势。在大多数模拟结果中,碳纳米管GBs及其相应的GP GBs具有几乎相同的强度。碳纳米管和GP GBs之间的显著差异仅在扶手椅GBs的0°和30°附近发现。这些强度差异归因于碳纳米管gb中的裂纹稳定和结构重建。
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来源期刊
Journal of the Ceramic Society of Japan
Journal of the Ceramic Society of Japan 工程技术-材料科学:硅酸盐
CiteScore
2.10
自引率
18.20%
发文量
170
审稿时长
2 months
期刊介绍: The Journal of the Ceramic Society of Japan (JCS-Japan) publishes original experimental and theoretical researches and reviews on ceramic science, ceramic materials, and related fields, including composites and hybrids. JCS-Japan welcomes manuscripts on both fundamental and applied researches.
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