Temperature-dependent failure of atomically thin MoTe.

Context: In this study, we investigated the mechanical responses of molybdenum ditelluride (MoTe) using molecular dynamics (MD) simulations. Our key focus was on the tensile behavior of MoTe with trigonal prismatic phase (2H-MoTe) which was investigated under uniaxial tensile stress for both armchair and zigzag directions. Crack formation and propagation were examined to understand the fracture behavior of such material for varying temperatures. Additionally, the study also assesses the impact of temperature on Young's modulus and fracture stress-strain of a monolayer of 2H-MoTe.

Method: The investigation was done using molecular dynamics (MD) simulations using Stillinger-Weber (SW) potentials. The tensile behavior was simulated for temperature for 10 K and then from 100 to 600 K with a 100-K interval. The crack propagation and formation of 10 K and 300 K 2H-MoTe for both directions at different strain rates was analyzed using Ovito visualizer. All the simulations were conducted using a strain rate of 10 ps. The results show that the fracture strength of 2H-MoTe in the armchair and zigzag direction at 10 K is 16.33 GPa (11.43 N/m) and 13.71429 GPa (9.46 N/m) under a 24% and 18% fracture strain, respectively. The fracture strength of 2H-MoTe in the armchair and zigzag direction at 600 K is 10.81 GPa (7.56 N/m) and 10.13 GPa (7.09 N/m) under a 12.5% and 12.47% fracture strain, respectively.