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DALIAN UNIVERSITY OF TECHNOLOGY Login 中文
江诚鸣

Associate Professor
Supervisor of Doctorate Candidates
Supervisor of Master's Candidates


Gender:Male
Alma Mater:阿拉巴马大学
Degree:Doctoral Degree
School/Department:机械工程学院
E-Mail:jiangcm@dlut.edu.cn
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Current position: Home >> Scientific Research >> Paper Publications

Size-dependent Young's modulus in ZnO nanowires with strong surface atomic bonds

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Indexed by:期刊论文

Date of Publication:2018-03-23

Journal:NANOTECHNOLOGY

Included Journals:SCIE、EI、PubMed、Scopus

Volume:29

Issue:12

Page Number:125702

ISSN No.:0957-4484

Key Words:Young's modulus characterization; nanomaterials property; size-dependent; ZnO nanowire

Abstract:The mechanical properties of size-dependent nanowires are important in nano-electro-mechanical systems (NEMSs), and have attracted much research interest. Characterization of the size effect of nanowires in atmosphere directly to broaden their practical application instead of just in high vacuum situations, as reported previously, is desperately needed. In this study, we systematically studied the Young's modulus of vertical ZnO nanowires in atmosphere. The diameters ranged from 48 nm to 239 nm with a resonance method using non-contact atomic force microscopy. The values of Young's modulus in atmosphere present extremely strong increasing tendency with decreasing diameter of nanowire due to stronger surface atomic bonds compared with that in vacuum. A core-shell model for nanowires is proposed to explore the Young's modulus enhancement in atmosphere, which is correlated with atoms of oxygen occurring near the nanowire surface. The modified model is more accurate for analyzing the mechanical behavior of nanowires in atmosphere compared with the model in vacuum. Furthermore, it is possible to use this characterization method to measure the size-related elastic properties of similar wire-sharp nanomaterials in atmosphere and estimate the corresponding mechanical behavior. The study of the size-dependent Young's modulus in ZnO nanowires in atmosphere will improve the understanding of the mechanical properties of nanomaterials as well as providing guidance for applications in NEMSs, nanogenerators, biosensors and other related areas.