Mechanical properties and failure behavior of hexagonal boron nitride sheets with nano-cracks

[Display omitted] Cracks in nano-scale are common defects in the 2D materials fabricated by a chemical vapor deposition method. Mechanical performance of 2D materials might be affected significantly due to the presence of nano-cracks. In this work, the mechanical performance and failure behavior of...

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Bibliographic Details
Published in:Computational materials science 2017-12, Vol.140, p.356-366
Main Authors: Li, Nan, Ding, Ning, Qu, Shen, Liu, Long, Guo, Weimin, Wu, Chi-Man Lawrence
Format: Article
Language:English
Subjects:
Failure
Fracture
Hexagonal boron nitride
Mechanical property
Nano-crack
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Summary:[Display omitted] Cracks in nano-scale are common defects in the 2D materials fabricated by a chemical vapor deposition method. Mechanical performance of 2D materials might be affected significantly due to the presence of nano-cracks. In this work, the mechanical performance and failure behavior of h-BN sheets with nano-cracks were studied using molecular dynamics methods. The relationship between the mechanical properties of h-BN sheets and the type or size of cracks was analyzed. The effect of temperature and strain rate on the mechanical behaviors of h-BN sheets was discussed. Results showed that when the crack size was larger than the threshold value, the Young’s modulus of h-BN sheets decreased with the increase of the crack size linearly. The increasing crack size resulted in faster decrease of the Young’s modulus of the zigzag h-BN sheet than that of the armchair h-BN sheet. The fracture strength decreased rapidly with the increasing crack size first. Then, when the crack size reached a critical value, change of the fracture strength become minor. The mechanical properties of h-BN sheets with cracks were sensitive to the variation of temperature and strain rate. The information obtained in this work would be useful for estimating the mechanical performance and failure mechanism of h-BN sheets in future application.
ISSN:0927-0256
1879-0801
DOI:10.1016/j.commatsci.2017.09.011