DFT Study of Oxygen Ion Migration in Mg-Doped Cubic Zirconia

This work presents a theoretical investigation of ionic conductivity in cubic zirco-nia (c-ZrO₂) doped with magnesium, using density functional theory (DFT) with the hybrid B3LYP functional as implemented in the CRYSTAL23 software package. It was found that the spatial arrangement of magnesium atoms and oxygen vacancies signifi-cantly affects the energy barriers for oxygen ion migration. Configurations with mag-nesium located along and outside the migration path were analyzed. The results show that when Mg²⁺ is positioned along the migration trajectory and near an oxygen va-cancy, stable defect complexes are formed with minimal migration barriers ranging from 0.96 to 1.32 eV. An increased number of Mg atoms can lead to a further reduction in the barrier, although in certain configurations the barriers increase up to 3.0–4.6 eV. When doping occurs outside the migration path, the energy profile remains symmetric and moderate (0.9–1.1 eV), indicating only a weak background influence. These find-ings highlight the critical role of coordinated distribution of Mg atoms and oxygen va-cancies along the migration pathway in forming efficient ion-conducting channels. This insight offers potential for designing high-performance zirconia-based electro-lytes for solid oxide fuel cells and sensor applications.