TY - JOUR
T1 - Prediction of graphene's mechanical and fracture properties via peridynamics
AU - Liu, Xuefeng
AU - Yu, Peng
AU - Zheng, Baojing
AU - Oterkus, Erkan
AU - He, Xiaoqiao
AU - Lu, Chun
PY - 2024/3/15
Y1 - 2024/3/15
N2 - Although graphene is believed to be the strongest material, many properties of this material are still worth exploring and discovering, especially the influence of inevitable defects in its preparation on the mechanical and fracture properties which are of high significance. This work provides a new feasible way to study the mechanical and fracture properties of graphene. The novelties of this study are threefold: (1) A novel peridynamic (PD) model is proposed for polycrystalline graphene in which grains of large size exist; (2) The coupling effect of the pre-crack length and the grain size on the inverse pseudo Hall-Petch relation is revealed; (3) The results confirm the applicability of classical Griffith theory in brittle fracture analysis of graphene. Based on the proposed PD model, dependence of the mechanical and fracture properties on the grain size which changes from a few to hundreds of nanometers is investigated in this study. The fracture forms of graphene are consistent with the experimental observations. Based on the Griffith theory, the obtained fracture toughness such as K
c (i.e. 3.8MPam - 6.3MPam) or G
c (i.e. 14.0 J/m
2 – 40.9 J/m
2) is comparable with previously reported theoretical and experimental values, which proves the validity of the proposed PD model. Besides, the fracture toughness can be greatly enhanced by the blunt pre-crack tip. This work presents insights into mechanical failure of graphene and guidance on fragmentation of graphene for its practical use.
AB - Although graphene is believed to be the strongest material, many properties of this material are still worth exploring and discovering, especially the influence of inevitable defects in its preparation on the mechanical and fracture properties which are of high significance. This work provides a new feasible way to study the mechanical and fracture properties of graphene. The novelties of this study are threefold: (1) A novel peridynamic (PD) model is proposed for polycrystalline graphene in which grains of large size exist; (2) The coupling effect of the pre-crack length and the grain size on the inverse pseudo Hall-Petch relation is revealed; (3) The results confirm the applicability of classical Griffith theory in brittle fracture analysis of graphene. Based on the proposed PD model, dependence of the mechanical and fracture properties on the grain size which changes from a few to hundreds of nanometers is investigated in this study. The fracture forms of graphene are consistent with the experimental observations. Based on the Griffith theory, the obtained fracture toughness such as K
c (i.e. 3.8MPam - 6.3MPam) or G
c (i.e. 14.0 J/m
2 – 40.9 J/m
2) is comparable with previously reported theoretical and experimental values, which proves the validity of the proposed PD model. Besides, the fracture toughness can be greatly enhanced by the blunt pre-crack tip. This work presents insights into mechanical failure of graphene and guidance on fragmentation of graphene for its practical use.
KW - peridynamics
KW - mechanical property
KW - fracture
KW - graphene
UR - https://www.sciencedirect.com/journal/international-journal-of-mechanical-sciences
U2 - 10.1016/j.ijmecsci.2023.108914
DO - 10.1016/j.ijmecsci.2023.108914
M3 - Article
SN - 0020-7403
VL - 266
JO - International Journal of Mechanical Sciences
JF - International Journal of Mechanical Sciences
M1 - 108914
ER -