Mechanical properties of γ-graphyne nanotubes

gamma-Graphyne nanotubes (gamma-GNTs), which are formed by rolling up a gamma-graphyne sheet in a similar way to carbon nanotubes, exhibit unique mechanical properties due to the carbon atoms in the sp and sp(2) hybridized states. In this study, the mechanical properties of gamma-GNTs were investigated using molecular dynamics simulations. The effects of the dimensions, temperature, strain rate and the presence of a vacancy on the mechanical properties, i.e., Youngs modulus, fracture strength and fracture strain, were comprehensively studied. The results indicate that the mechanical properties of the gamma-GNTs are not sensitive to the length and strain rate, while the Youngs modulus increases with increasing diameter. Meanwhile, an obvious temperature-dependent mechanical behavior was also found due to the stronger thermal vibration of the atoms at a higher temperature, especially in terms of the fracture strength and fracture strain. In addition, the mechanical properties of the gamma-GNTs would be degraded with the existence of a vacancy, and they are more sensitive to the vacancy in the benzene rings than that in the acetylenic linkages, especially for the double-vacancy. The underlying mechanisms were analyzed from the stress distribution and fracture structure during tensile deformation.