In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation

In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation

Abstract Twin boundaries (TBs) have been observed in and introduced into nonmetallic materials in recent years, which brought new concepts for the design of new structural materials. However, the roles of TB on the mechanical properties and strengthening/softening of transition metal nitrides remain...

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Main Authors: Tao Fu, Xianghe Peng, Cheng Huang, Henggao Xiang, Shayuan Weng, Zhongchang Wang, Ning Hu
Format: Article
Language:English
Published: Nature Publishing Group 2017-07-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-017-05062-0
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spelling doaj-76ba2743af144c19a8fd71afc615b2b42020-12-08T02:35:49ZengNature Publishing GroupScientific Reports2045-23222017-07-01711910.1038/s41598-017-05062-0In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentationTao Fu0Xianghe Peng1Cheng Huang2Henggao Xiang3Shayuan Weng4Zhongchang Wang5Ning Hu6College of Aerospace Engineering, Chongqing UniversityCollege of Aerospace Engineering, Chongqing UniversityCollege of Aerospace Engineering, Chongqing UniversityCollege of Aerospace Engineering, Chongqing UniversityCollege of Aerospace Engineering, Chongqing UniversityInternational Iberian Nanotechnology Laboratory (INL), Avenida Mestre Jose VeigaCollege of Aerospace Engineering, Chongqing UniversityAbstract Twin boundaries (TBs) have been observed in and introduced into nonmetallic materials in recent years, which brought new concepts for the design of new structural materials. However, the roles of TB on the mechanical properties and strengthening/softening of transition metal nitrides remain unclear. To investigate the TB effects and the in-plane anisotropy, nanoindentations on VN (111) films with and without TB were simulated with molecular dynamics, in which a cylindrical indenter was used, and its longitudinal axis were assigned along <112> and <110>, respectively. We found that the effect of the indenter orientation is insignificant in the elastic stage, but significant in the following inelastic deformation. Different deformation mechanisms can be found for inelastic deformation, such as twinning and dislocation glide. The migration of TB can be observed, which may release the internal stress, resulting in softening; while the dislocation locking and pileup at TB can enhance the strength. We also found that the strengthening/softening induced by TB depends on the deformation mechanisms induced by indenter directions.https://doi.org/10.1038/s41598-017-05062-0
collection DOAJ
language English
format Article
sources DOAJ
author Tao Fu
Xianghe Peng
Cheng Huang
Henggao Xiang
Shayuan Weng
Zhongchang Wang
Ning Hu
spellingShingle Tao Fu
Xianghe Peng
Cheng Huang
Henggao Xiang
Shayuan Weng
Zhongchang Wang
Ning Hu
In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
Scientific Reports
author_facet Tao Fu
Xianghe Peng
Cheng Huang
Henggao Xiang
Shayuan Weng
Zhongchang Wang
Ning Hu
author_sort Tao Fu
title In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
title_short In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
title_full In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
title_fullStr In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
title_full_unstemmed In-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
title_sort in-plane anisotropy and twin boundary effects in vanadium nitride under nanoindentation
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2017-07-01
description Abstract Twin boundaries (TBs) have been observed in and introduced into nonmetallic materials in recent years, which brought new concepts for the design of new structural materials. However, the roles of TB on the mechanical properties and strengthening/softening of transition metal nitrides remain unclear. To investigate the TB effects and the in-plane anisotropy, nanoindentations on VN (111) films with and without TB were simulated with molecular dynamics, in which a cylindrical indenter was used, and its longitudinal axis were assigned along <112> and <110>, respectively. We found that the effect of the indenter orientation is insignificant in the elastic stage, but significant in the following inelastic deformation. Different deformation mechanisms can be found for inelastic deformation, such as twinning and dislocation glide. The migration of TB can be observed, which may release the internal stress, resulting in softening; while the dislocation locking and pileup at TB can enhance the strength. We also found that the strengthening/softening induced by TB depends on the deformation mechanisms induced by indenter directions.
url https://doi.org/10.1038/s41598-017-05062-0
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AT xianghepeng inplaneanisotropyandtwinboundaryeffectsinvanadiumnitrideundernanoindentation
AT chenghuang inplaneanisotropyandtwinboundaryeffectsinvanadiumnitrideundernanoindentation
AT henggaoxiang inplaneanisotropyandtwinboundaryeffectsinvanadiumnitrideundernanoindentation
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