Structure and energetics of nanotwins in cubic boron nitrides

Shijian Zheng; Ruifeng Zhang; Rong Huang; Takashi Taniguchi; Xiuliang Ma; Yuichi Ikuhara; Irene J. Beyerlein

doi:10.1063/1.4961240

Structure and energetics of nanotwins in cubic boron nitrides

Shijian Zheng^*
, Ruifeng Zhang
, Rong Huang
, Takashi Taniguchi
, Xiuliang Ma
, Yuichi Ikuhara
, Irene J. Beyerlein

^*此作品的通讯作者

材料科学与工程学院

CAS - Institute of Metal Research
East China Normal University
National Institute for Materials Science Tsukuba
Japan Fine Ceramics Center
The University of Tokyo
Los Alamos National Laboratory Theoretical Division

科研成果: 期刊稿件 › 文章 › 同行评审

23 引用（Scopus）

摘要

Recently, nanotwinned cubic boron nitrides (NT c-BN) have demonstrated extraordinary leaps in hardness. However, an understanding of the underlying mechanisms that enable nanotwins to give orders of magnitude increases in material hardness is still lacking. Here, using transmission electron microscopy, we report that the defect density of twin boundaries depends on nanotwin thickness, becoming defect-free, and hence more stable, as it decreases below 5 nm. Using ab initio density functional theory calculations, we reveal that the Shockley partials, which may dominate plastic deformation in c-BNs, show a high energetic barrier. We also report that the c-BN twin boundary has an asymmetrically charged electronic structure that would resist migration of the twin boundary under stress. These results provide important insight into possible nanotwin hardening mechanisms in c-BN, as well as how to design these nanostructured materials to reach their full potential in hardness and strength.

源语言	英语
文章编号	081901
期刊	Applied Physics Letters
卷	109
期	8
DOI	https://doi.org/10.1063/1.4961240
出版状态	已出版 - 22 8月 2016

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abstract = "Recently, nanotwinned cubic boron nitrides (NT c-BN) have demonstrated extraordinary leaps in hardness. However, an understanding of the underlying mechanisms that enable nanotwins to give orders of magnitude increases in material hardness is still lacking. Here, using transmission electron microscopy, we report that the defect density of twin boundaries depends on nanotwin thickness, becoming defect-free, and hence more stable, as it decreases below 5 nm. Using ab initio density functional theory calculations, we reveal that the Shockley partials, which may dominate plastic deformation in c-BNs, show a high energetic barrier. We also report that the c-BN twin boundary has an asymmetrically charged electronic structure that would resist migration of the twin boundary under stress. These results provide important insight into possible nanotwin hardening mechanisms in c-BN, as well as how to design these nanostructured materials to reach their full potential in hardness and strength.",

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AU - Zheng, Shijian

AU - Zhang, Ruifeng

AU - Huang, Rong

AU - Taniguchi, Takashi

AU - Ma, Xiuliang

AU - Ikuhara, Yuichi

AU - Beyerlein, Irene J.

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N2 - Recently, nanotwinned cubic boron nitrides (NT c-BN) have demonstrated extraordinary leaps in hardness. However, an understanding of the underlying mechanisms that enable nanotwins to give orders of magnitude increases in material hardness is still lacking. Here, using transmission electron microscopy, we report that the defect density of twin boundaries depends on nanotwin thickness, becoming defect-free, and hence more stable, as it decreases below 5 nm. Using ab initio density functional theory calculations, we reveal that the Shockley partials, which may dominate plastic deformation in c-BNs, show a high energetic barrier. We also report that the c-BN twin boundary has an asymmetrically charged electronic structure that would resist migration of the twin boundary under stress. These results provide important insight into possible nanotwin hardening mechanisms in c-BN, as well as how to design these nanostructured materials to reach their full potential in hardness and strength.

AB - Recently, nanotwinned cubic boron nitrides (NT c-BN) have demonstrated extraordinary leaps in hardness. However, an understanding of the underlying mechanisms that enable nanotwins to give orders of magnitude increases in material hardness is still lacking. Here, using transmission electron microscopy, we report that the defect density of twin boundaries depends on nanotwin thickness, becoming defect-free, and hence more stable, as it decreases below 5 nm. Using ab initio density functional theory calculations, we reveal that the Shockley partials, which may dominate plastic deformation in c-BNs, show a high energetic barrier. We also report that the c-BN twin boundary has an asymmetrically charged electronic structure that would resist migration of the twin boundary under stress. These results provide important insight into possible nanotwin hardening mechanisms in c-BN, as well as how to design these nanostructured materials to reach their full potential in hardness and strength.

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Structure and energetics of nanotwins in cubic boron nitrides

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