Atomistic deformation mechanisms in twinned copper nanospheres

Jianjun Bian; Xinrui Niu; Hao Zhang; Gangfeng Wang

doi:10.1186/1556-276X-9-335

Atomistic deformation mechanisms in twinned copper nanospheres

Jianjun Bian
, Xinrui Niu
, Hao Zhang
, Gangfeng Wang

College of Engineering

SUNY Polytechnic Institute

Xi'an Jiaotong University
University of Alberta

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

In the present study, we perform molecular dynamic simulations to investigate the compression response and atomistic deformation mechanisms of twinned nanospheres. The relationship between load and compression depth is calculated for various twin spacing and loading directions. Then, the overall elastic properties and the underlying plastic deformation mechanisms are illuminated. Twin boundaries (TBs) act as obstacles to dislocation motion and lead to strengthening. As the loading direction varies, the plastic deformation transfers from dislocations intersecting with TBs, slipping parallel to TBs, and then to being restrained by TBs. The strengthening of TBs depends strongly on the twin spacing.

Original language	English
Article number	335
Pages (from-to)	1-7
Number of pages	7
Journal	Nanoscale Research Letters
Volume	9
Issue number	1
DOIs	https://doi.org/10.1186/1556-276X-9-335
State	Published - 2014

Keywords

Nanosphere
Strengthening
Twin boundary

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10.1186/1556-276X-9-335

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abstract = "In the present study, we perform molecular dynamic simulations to investigate the compression response and atomistic deformation mechanisms of twinned nanospheres. The relationship between load and compression depth is calculated for various twin spacing and loading directions. Then, the overall elastic properties and the underlying plastic deformation mechanisms are illuminated. Twin boundaries (TBs) act as obstacles to dislocation motion and lead to strengthening. As the loading direction varies, the plastic deformation transfers from dislocations intersecting with TBs, slipping parallel to TBs, and then to being restrained by TBs. The strengthening of TBs depends strongly on the twin spacing.",

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T1 - Atomistic deformation mechanisms in twinned copper nanospheres

AU - Bian, Jianjun

AU - Niu, Xinrui

AU - Zhang, Hao

AU - Wang, Gangfeng

PY - 2014

Y1 - 2014

N2 - In the present study, we perform molecular dynamic simulations to investigate the compression response and atomistic deformation mechanisms of twinned nanospheres. The relationship between load and compression depth is calculated for various twin spacing and loading directions. Then, the overall elastic properties and the underlying plastic deformation mechanisms are illuminated. Twin boundaries (TBs) act as obstacles to dislocation motion and lead to strengthening. As the loading direction varies, the plastic deformation transfers from dislocations intersecting with TBs, slipping parallel to TBs, and then to being restrained by TBs. The strengthening of TBs depends strongly on the twin spacing.

AB - In the present study, we perform molecular dynamic simulations to investigate the compression response and atomistic deformation mechanisms of twinned nanospheres. The relationship between load and compression depth is calculated for various twin spacing and loading directions. Then, the overall elastic properties and the underlying plastic deformation mechanisms are illuminated. Twin boundaries (TBs) act as obstacles to dislocation motion and lead to strengthening. As the loading direction varies, the plastic deformation transfers from dislocations intersecting with TBs, slipping parallel to TBs, and then to being restrained by TBs. The strengthening of TBs depends strongly on the twin spacing.

KW - Nanosphere

KW - Strengthening

KW - Twin boundary

UR - https://www.scopus.com/pages/publications/84940035930

U2 - 10.1186/1556-276X-9-335

DO - 10.1186/1556-276X-9-335

M3 - Article

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EP - 7

JO - Nanoscale Research Letters

JF - Nanoscale Research Letters

IS - 1

M1 - 335

ER -

Atomistic deformation mechanisms in twinned copper nanospheres

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Keywords

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