Molecular dynamics simulation on burst and arrest of stacking faults in nanocrystalline Cuunder nanoindentation

Xin-Ling Ma; Wei Yang

doi:10.1088/0957-4484/14/11/009

Nanotechnology

Molecular dynamics simulation on burst and arrest of stacking faults in nanocrystalline Cu under nanoindentation

Xin-Ling Ma¹ and Wei Yang

Published 7 October 2003 • IOP Publishing Ltd
Nanotechnology, Volume 14, Number 11 Citation Xin-Ling Ma and Wei Yang 2003 Nanotechnology 14 1208 DOI 10.1088/0957-4484/14/11/009

Download Article PDF

Article metrics

2446 Total downloads

Submit

Submit to this Journal

Permissions

Get permission to re-use this article

Author affiliations

¹ Department of Engineering Mechanics, Tsinghua University, Beijing 100084, People's Republic of China

² Author to whom any correspondence should be addressed

Dates

Received 21 May 2003
Published 7 October 2003

Buy this article in print

Journal RSS

Sign up for new issue notifications

Abstract

Nanoindentation induces versatile deformation mechanisms. The situation is examined here for the case of nanocrystalline Cu by means of parallel molecular dynamics simulations. The indenter is applied to the grain boundary (GB) or to the grain interior. The inter-atomic interaction of Cu is modelled by both the Lennard-Jones potential and the embedded atom method potential. The burst and arrest of stacking faults hold the key for the plastic deformation of nanocrystalline Cu under nanoindentation, in clear contrast to the case of nanoindentation on single-crystal Cu. The following descending order of indentation resistance is found: single crystal (or polycrystal of large grain size), nanocrystal when indented on the grain interior, and nanocrystal indented on the GB.

Export citation and abstract BibTeX RIS

Previous article in issue

Next article in issue

Please wait… references are loading.