Wall-thickness-dependent strength of nanotubular ZnO

机译：纳米管ZnO的壁厚依赖性强度

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摘要

We fabricate nanotubular ZnO with wall thickness of 45, 92, 123 nm using nanoporous gold (np-Au) with ligament diameter at necks of 1.43 μm as sacrificial template. Through micro-tensile and micro-compressive testing of nanotubular ZnO structures, we find that the exponent m in

\bar{σ} \propto {\bar{ρ}}^{m}

, where

\bar{σ}

is the relative strength and

\bar{ρ}

is the relative density, for tension is 1.09 and for compression is 0.63. Both exponents are lower than the value of 1.5 in the Gibson-Ashby model that describes the relation between relative strength and relative density where the strength of constituent material is independent of external size, which indicates that strength of constituent ZnO increases as wall thickness decreases. We find, based on hole-nanoindentation and glazing incidence X-ray diffraction, that this wall-thickness-dependent strength of nanotubular ZnO is not caused by strengthening of constituent ZnO by size reduction at the nanoscale. Finite element analysis suggests that the wall-thickness-dependent strength of nanotubular ZnO originates from nanotubular structures formed on ligaments of np-Au.

机译：我们以韧带直径为1.43μm的纳米孔金（np-Au）作为牺牲模板，制备了壁厚为45、92、123 nm的纳米管ZnO。通过对纳米管ZnO结构的微拉伸和微压缩测试，我们发现

<移动者口音=“ true”> σ？\propto<移动者口音=“ true”> ρ？m，其中<移动器重音=“ true”> σ是相对强度，ρ？是相对密度，拉力为1.09，压缩力为0.63。这两个指数均低于描述相对强度和相对密度之间关系的Gibson-Ashby模型中的1.5值，其中组成材料的强度与外部尺寸无关，这表明组成ZnO的强度随壁厚的减小而增加。我们基于空穴纳米压痕和玻璃入射X射线衍射发现，纳米管ZnO的壁厚依赖性强度不是由纳米级尺寸减小引起的ZnO增强而引起的。有限元分析表明，纳米管ZnO的壁厚依赖性强度源自np-Au韧带上形成的纳米管结构。

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期刊名称 Scientific Reports
作者
Na-Ri Kang; Young-Cheon Kim; Hansol Jeon; Seong Keun Kim; Jae-il Jang; Heung Nam Han; Ju-Young Kim;
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年(卷),期 -1(7),-1
年度 -1
页码 4327
总页数 10
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5. Analysis of the Temperature Dependent Band-edge Distribution as a Function of Annealing in ZnO and ZnO-Based Thin Film Alloys [D] . Canul, Amrah. 2020

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6. Introducing Mg-4Zn-3Gd-1Ca/ZnO nanocomposite with compressive strengths matching/exceeding that of mild steel [O] . Y. Chen, S. Tekumalla, Y. B. Guo, -1

机译：引入抗压强度匹配/超过低碳钢的Mg-4Zn-3Gd-1Ca / ZnO纳米复合材料
7. Wall-thickness-dependent strength of nanotubular ZnO [O] . Kang Na-Ri, Kim Young-Cheon, Jeon Hansol, 2017

机译：纳米管ZnO的壁厚依赖性强度

Wall-thickness-dependent strength of nanotubular ZnO

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