Journal
THIN-WALLED STRUCTURES
Volume 195, Issue -, Pages -Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.tws.2023.111341
Keywords
Nanoindentation; Mechanical properties; Graphene/h-BN; vdW heterostructure; Molecular dynamics simulation; Finite element analysis
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Two-dimensional nanomaterials like graphene and h-BN have high mechanical strength and thermal conductivity, making them ideal reinforcing fillers for impact protection materials, phase change materials, and thermal interface materials. However, the mechanical properties of graphene/h-BN heterostructures have not been widely explored. This study used molecular dynamics simulations and finite element analysis to investigate the mechanical properties, fracture mechanisms, and manipulation techniques of graphene/h-BN heterostructures. The results show that heterogeneous GBN has excellent performance in resisting bending deformation, and its size-dependent performance can be manipulated through hydrogenation and layer number.
Two-dimensional nanomaterials, such as graphene and h-BN have been widely used as reinforcing fillers for polymer-based impact protection materials, phase change materials (PCM) or thermal interface materials (TIM) due to its exceptional high mechanical strength and high thermal conductivity. But the mechanical properties of graphene/h-BN (GBN) van der Waals (vdW) heterostructures remain largely unexplored. Herein we carry out intensive nanoindentation tests on GBN by using molecular dynamics simulations as well as finite element analysis to investigate its mechanical properties, fracture mechanisms as well as the effective manipulation techniques for force and deformation. Compared with its homogeneous counterparts (pure graphene or pure hBN), the heterogeneous GBN possess excellent performance in resisting bending deformation in terms of the indentation load and depth. The size-dependent performance of GBN can be effectively manipulated by hydrogenation in the middle graphene and layer number, except the composition diffusion interface. This comprehensive study confirms that the high strength and high flexibility of GBN endow it with great potential in the applications of impact protection and thermal management in PCM and TIM.
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