Nanoscale ice fracture by molecular dynamics simulations (1907.09018v1)

Abstract: In this work, we conducted molecular dynamics simulations to study the fracture mechanism of ice crystals in a bulk phase and at ice-ice interfaces at the atomistic scale. We show that there exists a narrow disordered interfacial layer between two Ih ice structures. The width of the interfacial layer is determined to be about the size of two water molecules. Upon deformation, the stress response of ice at interface show significantly anisotropic behaviors depending on the direction of deformation. Bulk-like behavior is observed when direction of deformation being orthogonal to the direction of interfacial plane. Significantly smaller fracture stress and yield strain occurs if the deformation is along interfacial plane. This result illustrates the dominant role played by the small amount of disordered water molecules at interface in altering mechanical strength of an interfacial structure.