Interfaces, grain boundaries, and dislocations are known to have significant impact on the transport properties within materials. Even so, it is still not clear how the structure of interfaces influence the mobility and concentration of carriers that are responsible for transport. Using low angle twist grain boundaries in MgO as a model system for semi-coherent interfaces more generally, we examine the structural and kinetic properties of vacancies. These boundaries are characterized by a network of screw dislocations. Vacancies of both types, Mg and O, are strongly attracted to the dislocation network, residing preferentially at the misfit dislocation intersections (MDIs). However, the vacancies can lower their energy by splitting into two parts, which then repel each other along the dislocation line between two MDIs because of electrostatic repulsion, further lowering their energy.



This dissociated structure has important consequences for transport, as the free energy of the dissociated vacancies decreases with decreasing twist angle, leading to an increase in the net migration barrier for diffusion as revealed by molecular dynamics simulations. Similar behavior is observed in BaO and NaCl, highlighting the generality of the behavior. We analyze the structure of the dissociated vacancies as a pair of jogs on the dislocation and construct a model containing electrostatic and elastic contributions that qualitatively describe the energetics of the dissociated vacancy. Finally, we examine the nature of this mechanism in other ionic compounds without a rocksalt structure. Our results represent the first validation of a mechanism for vacancy dissociation on screw dislocations in ionic materials first discussed by Thomson and Balluffi in 1962.