Modeling the effects of particles, interstitials, vacancies and tip geometry on indentation-induced plasticity

Abstract

In this work, which is a follow-up of an earlier work by the authors in this journal, we discuss the effects of particles, interstitials, vacancies and indenter-tip geometry on indentation-induced plasticity. A nano-indentation model based on a close-packed array of straws was used. Upon indentation with a cylindrical indenter, the results observed in situ, match qualitatively computer atomistic and finite-element simulation models. This model helps explain the phenomenon and physical reasons for annihilation of vacancies. It also shows the strong effect of interstitials on the inception of plasticity at their sites. It shows that a rigid particle acts as a stress concentrator even away from the indenter. On indentation with a flat indenter, curling of atoms at the indenter edges was observed, along with slip lines reported in the literature.