Deformation behaviors of Au nanotubes under torsion by molecular dynamics simulations

Yeong Maw Hwang; Cheng Tang Pan; Ying Xu Lu; Sheng Rui Jian; Jenh-Yih Juang

doi:10.1063/1.5030989

Deformation behaviors of Au nanotubes under torsion by molecular dynamics simulations

Yeong Maw Hwang, Cheng Tang Pan, Ying Xu Lu, Sheng Rui Jian^*, Jenh-Yih Juang

^*此作品的通信作者

電子物理學系

研究成果: Article › 同行評審

4 引文斯高帕斯（Scopus）

摘要

In this study, the mechanical deformation behaviors of Au nanotubes (Au-NTs) under torsional stress are investigated using molecular dynamics (MD) simulations. The inter-atomic interaction is modeled using the embedded-atom potential. In particular, the effects of loading rate, thickness and length of the nanotube, as well as the thermal effects were systematically explored. The results indicated that higher loading rate, longer length and thinner wall thickness all led to a larger value of critical torsional angle (θ_cr), which signifies the onset of plastic deformation. On the other hand, θ_cr decreases with increasing temperature in all simulated results. Moreover, the torsional buckling deformation behavior and geometrical instability are found to strongly depend on the length of Au-NTs, the applied strain rate and temperature with vastly different underlying mechanisms.

原文	English
文章編號	085204
期刊	AIP Advances
卷	8
發行號	8
DOIs	https://doi.org/10.1063/1.5030989
出版狀態	Published - 1 8月 2018

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title = "Deformation behaviors of Au nanotubes under torsion by molecular dynamics simulations",

abstract = "In this study, the mechanical deformation behaviors of Au nanotubes (Au-NTs) under torsional stress are investigated using molecular dynamics (MD) simulations. The inter-atomic interaction is modeled using the embedded-atom potential. In particular, the effects of loading rate, thickness and length of the nanotube, as well as the thermal effects were systematically explored. The results indicated that higher loading rate, longer length and thinner wall thickness all led to a larger value of critical torsional angle (θcr), which signifies the onset of plastic deformation. On the other hand, θcr decreases with increasing temperature in all simulated results. Moreover, the torsional buckling deformation behavior and geometrical instability are found to strongly depend on the length of Au-NTs, the applied strain rate and temperature with vastly different underlying mechanisms.",

author = "Hwang, {Yeong Maw} and Pan, {Cheng Tang} and Lu, {Ying Xu} and Jian, {Sheng Rui} and Jenh-Yih Juang",

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AU - Hwang, Yeong Maw

AU - Pan, Cheng Tang

AU - Lu, Ying Xu

AU - Jian, Sheng Rui

AU - Juang, Jenh-Yih

PY - 2018/8/1

Y1 - 2018/8/1

N2 - In this study, the mechanical deformation behaviors of Au nanotubes (Au-NTs) under torsional stress are investigated using molecular dynamics (MD) simulations. The inter-atomic interaction is modeled using the embedded-atom potential. In particular, the effects of loading rate, thickness and length of the nanotube, as well as the thermal effects were systematically explored. The results indicated that higher loading rate, longer length and thinner wall thickness all led to a larger value of critical torsional angle (θcr), which signifies the onset of plastic deformation. On the other hand, θcr decreases with increasing temperature in all simulated results. Moreover, the torsional buckling deformation behavior and geometrical instability are found to strongly depend on the length of Au-NTs, the applied strain rate and temperature with vastly different underlying mechanisms.

AB - In this study, the mechanical deformation behaviors of Au nanotubes (Au-NTs) under torsional stress are investigated using molecular dynamics (MD) simulations. The inter-atomic interaction is modeled using the embedded-atom potential. In particular, the effects of loading rate, thickness and length of the nanotube, as well as the thermal effects were systematically explored. The results indicated that higher loading rate, longer length and thinner wall thickness all led to a larger value of critical torsional angle (θcr), which signifies the onset of plastic deformation. On the other hand, θcr decreases with increasing temperature in all simulated results. Moreover, the torsional buckling deformation behavior and geometrical instability are found to strongly depend on the length of Au-NTs, the applied strain rate and temperature with vastly different underlying mechanisms.

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Deformation behaviors of Au nanotubes under torsion by molecular dynamics simulations

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