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We determine the interaction between an $1/2\ensuremath{\langle}110\ensuremath{\rangle}{\overline{1}10}$ edge dislocation and charged vacancies in MgO, using both molecular static simulations and the elasticity theory developed in the framework of the elastic… Click to show full abstract
We determine the interaction between an $1/2\ensuremath{\langle}110\ensuremath{\rangle}{\overline{1}10}$ edge dislocation and charged vacancies in MgO, using both molecular static simulations and the elasticity theory developed in the framework of the elastic dipole approach. In this study, the confrontation of these two methods highlights the specific role of the dislocation core structure on the interaction. We thus show that in MgO, the edge dislocation core, within a region across the glide planes that expands over several Burgers vector, is strongly attractive for vacancies, especially those of oxygen. However, the resulting pinning force on the dislocation remains weak and should not contribute to a significant hardening.
Journal Title: Physical Review Materials
Year Published: 2021
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