Superstrength through Nanotwinning

Qi An; William A. Goddard; Kelvin Y. Xie; Gi Dong Sim; Kevin J. Hemker; Tyler Munhollon; M. Fatih Toksoy; Richard A. Haber

doi:10.1021/acs.nanolett.6b03414

Superstrength through Nanotwinning

Qi An
, William A. Goddard
, Kelvin Y. Xie
, Gi Dong Sim
, Kevin J. Hemker
, Tyler Munhollon
, M. Fatih Toksoy
, Richard A. Haber

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

The theoretical strength of a material is the minimum stress to deform or fracture the perfect single crystal material that has no defects. This theoretical strength is considered as an upper bound on the attainable strength for a real crystal. In contradiction to this expectation, we use quantum mechanics (QM) simulations to show that for the boron carbide (B₄C) hard ceramic, this theoretical shear strength can be exceeded by 11% by imposing nanoscale twins. We also predict from QM that the indentation strength of nanotwinned B₄C is 12% higher than that of the perfect crystal. Further, we validate this effect experimentally, showing that nanotwinned samples are harder by 2.3% than the twin-free counterpart of B₄C. The origin of this strengthening mechanism is suppression of twin boundary (TB) slip within the nanotwins due to the directional nature of covalent bonds at the TB.

langue originale	Anglais
Pages (de - à)	7573-7579
Nombre de pages	7
journal	Nano Letters
Volume	16
Numéro de publication	12
Les DOIs	https://doi.org/10.1021/acs.nanolett.6b03414
état	Publié - 14 déc. 2016
Modification externe	Oui

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10.1021/acs.nanolett.6b03414

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title = "Superstrength through Nanotwinning",

abstract = "The theoretical strength of a material is the minimum stress to deform or fracture the perfect single crystal material that has no defects. This theoretical strength is considered as an upper bound on the attainable strength for a real crystal. In contradiction to this expectation, we use quantum mechanics (QM) simulations to show that for the boron carbide (B4C) hard ceramic, this theoretical shear strength can be exceeded by 11\% by imposing nanoscale twins. We also predict from QM that the indentation strength of nanotwinned B4C is 12\% higher than that of the perfect crystal. Further, we validate this effect experimentally, showing that nanotwinned samples are harder by 2.3\% than the twin-free counterpart of B4C. The origin of this strengthening mechanism is suppression of twin boundary (TB) slip within the nanotwins due to the directional nature of covalent bonds at the TB.",

keywords = "DFT, Superhard ceramics, deformation mechanism, hardness, nanoindentation",

author = "Qi An and Goddard, \{William A.\} and Xie, \{Kelvin Y.\} and Sim, \{Gi Dong\} and Hemker, \{Kevin J.\} and Tyler Munhollon and \{Fatih Toksoy\}, M. and Haber, \{Richard A.\}",

note = "Publisher Copyright: {\textcopyright} 2016 American Chemical Society.",

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doi = "10.1021/acs.nanolett.6b03414",

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TY - JOUR

T1 - Superstrength through Nanotwinning

AU - An, Qi

AU - Goddard, William A.

AU - Xie, Kelvin Y.

AU - Sim, Gi Dong

AU - Hemker, Kevin J.

AU - Munhollon, Tyler

AU - Fatih Toksoy, M.

AU - Haber, Richard A.

PY - 2016/12/14

Y1 - 2016/12/14

N2 - The theoretical strength of a material is the minimum stress to deform or fracture the perfect single crystal material that has no defects. This theoretical strength is considered as an upper bound on the attainable strength for a real crystal. In contradiction to this expectation, we use quantum mechanics (QM) simulations to show that for the boron carbide (B4C) hard ceramic, this theoretical shear strength can be exceeded by 11% by imposing nanoscale twins. We also predict from QM that the indentation strength of nanotwinned B4C is 12% higher than that of the perfect crystal. Further, we validate this effect experimentally, showing that nanotwinned samples are harder by 2.3% than the twin-free counterpart of B4C. The origin of this strengthening mechanism is suppression of twin boundary (TB) slip within the nanotwins due to the directional nature of covalent bonds at the TB.

AB - The theoretical strength of a material is the minimum stress to deform or fracture the perfect single crystal material that has no defects. This theoretical strength is considered as an upper bound on the attainable strength for a real crystal. In contradiction to this expectation, we use quantum mechanics (QM) simulations to show that for the boron carbide (B4C) hard ceramic, this theoretical shear strength can be exceeded by 11% by imposing nanoscale twins. We also predict from QM that the indentation strength of nanotwinned B4C is 12% higher than that of the perfect crystal. Further, we validate this effect experimentally, showing that nanotwinned samples are harder by 2.3% than the twin-free counterpart of B4C. The origin of this strengthening mechanism is suppression of twin boundary (TB) slip within the nanotwins due to the directional nature of covalent bonds at the TB.

KW - DFT

KW - Superhard ceramics

KW - deformation mechanism

KW - hardness

KW - nanoindentation

UR - https://www.scopus.com/pages/publications/85006499412

U2 - 10.1021/acs.nanolett.6b03414

DO - 10.1021/acs.nanolett.6b03414

M3 - Article

AN - SCOPUS:85006499412

SN - 1530-6984

VL - 16

SP - 7573

EP - 7579

JO - Nano Letters

JF - Nano Letters

IS - 12

ER -

Superstrength through Nanotwinning

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