Mechanical behaviour of 2D hybrid structure fabricated by doping graphene with triangular h-BN cells

A two dimensional (2D) hybrid structure has been fabricated by doping graphene with hexagonal boron nitride (h-BN) cells. Substantial changes are expected as carbon-carbon (C) bonds are substituted by B-N bonds and C-B and C-N bonds are formed between the BN cells and graphene. In this paper, molecular dynamics simulations are performed to explore the tensile behaviour and fracture mechanisms of the 2D HS, and reveal how and to what extent the BN cells impact its overall tensile properties. A comprehensive study of free boundary effects is also conducted for the first time for 2D materials. Herein, the 2D nonlinear elastic constitutive relation has been formulated in terms of the equivalent elastic modulus Y-e that decreases almost linearly with BN content alpha due to the distinct elastic properties between B-N bonds and C-C bonds. The downward trend of the fracture stress with growing alpha is also achieved due to the alpha - dependence of Y-e and the limit on the fracture strain imposed by the newly formed C-B bonds. In addition, evidence has been accumulated showing that the free boundaries can significantly decrease the elastic moduli and fracture stress but largely enhance the fracture toughness of the 2D nanosheets.

Automated summary

A two dimensional hybrid structure was fabricated by doping graphene with hexagonal boron nitride cells, leading to substantial changes in the material's properties. Molecular dynamics simulations were used to explore the tensile behavior of the structure and its fracture mechanisms, revealing the impact of the BN cells on its overall tensile properties. The study also found that free boundaries could significantly decrease elastic moduli and fracture stress while enhancing fracture toughness of the 2D nanosheets.