Force-induced breakdown of flexible polymerized membrane

Abstract

We consider the fracture of a free-standing two-dimensional (2D) elastic-brittle network to be used as protective coating subject to constant tensile stress applied on its rim. Using a Molecular Dynamics simulation with Langevin thermostat, we investigate the scission and recombination of bonds, and the formation of cracks in the 2D graphene-like hexagonal sheet for different pulling force f and temperature T. We find that bond rupture occurs almost always at the sheet periphery and the First Mean Breakage Time <τ> of bonds decays with membrane size as <τ> N-β where β ≈ 0.50 0.03 and N denotes the number of atoms in the membrane. The probability distribution of bond scission times t is given by a Poisson function W(t) t1/3 (-t / <τ>). The mean failure time <τr> that takes to rip-off the sheet declines with growing size N as a power law <τr> N-φ(f). We also find <τr> ( U0/kBT) where the nucleation barrier for crack formation U0 f-2, in agreement with Griffith's theory. <τr> displays an Arrhenian dependence of <τr> on temperature T. Our results indicate a rapid increase in crack spreading velocity with growing external tension f.