Equilibrium point defect concentrations in MgO: Understanding the mechanisms of conduction and diffusion and the role of Fe impurities

By simultaneously solving the governing equations for defect formation and the relative conservation laws, the authors have made a general calculation of equilibrium concentrations of point defects in MgO as functions of temperature, oxygen fugacity (fO{sub 2}), and Fe content. The aim of this work is to better understand the mechanisms that control the transport processes of electrical conduction and diffusion and the oxidation state of Fe. The present model suggests the following regimes that are consistent with several kinds of experiments. Electrical conduction is dominated at low fO{sub 2} by electrons and O vacancies and at high fO{sub 2} by Fe{sup 3+} on Mg sites (Fe{sm bullet}{sub Mg}) and Mg vacancies. Defect associates involving Fe{sm bullet}{sub Mg} and Mg vacancies are required to explain experimental data on oxidation state of Fe as a function of fO{sub 2}, temperature, and Fe content. At high temperatures, intrinsic formation of Mg and O vacancies are important controls on Mg diffusivity; Fe{sup 3+} impurities at intermediate temperatures and impurity-vacancy associates at low temperatures are important. Associates involving Mg and O vacancies at low temperatures and unassociated O vacancies at higher temperatures are important for O diffusivity. The concentration of Fe at which themore » concentrations of other defects are affected strongly depends on fO{sub 2} and temperature. Even minute amounts of Fe (i.e., 1 ppm) may affect properties at temperatures below 1,273 K and fO{sub 2} above 10{sup {minus}15} MPa, whereas at temperatures above 1,873 K and fO{sub 2} below 10{sup {minus}14} MPa, material properties may be relatively insensitive up to 1% Fe content.« less