First-Principle Study of Hole Localization in La1-XSrxFeO3-δ

The durability and efficiency of Solid Oxide Fuel Cells or Electrolysis Cells (SOFC/SOEC) depend on the reaction mechanisms taking place within the electrodes. These mechanisms combine a series of elementary steps including mass and charge transfers along with chemical and electrochemical reactions. These processes are still not precisely understood as they involve complex physical phenomena occurring at the atomic scale. Therefore, it is still required to carry out some fundamental studies to better unravel the basic mechanisms involved in the material properties such as the electronic or ionic conductivity, etc. For such basic investigations, the ab-initio modeling is nowadays recognized as a powerful and relevant method. In this context, this work aims to provide deeper insights into the mechanisms at atomic scale by using Density Functional Theory (DFT) calculations. La1-xSrxCoyFe1-yO3-δ (LSCF) and LSCF-based materials are Mixed Ionic-Electronic Conductors, which are commonly used as oxygen electrode for the SOFCs/SOECs [1]. LSCF is a perovskite oxide that contains two transition metals, i.e. cobalt and iron. Owing to the complexity of this system, our work was first devoted to the parent material La1-xSrxFeO3 (LSF), which was here studied by DFT+U calculations. A special focus was paid to finely describe the localization of holes and the formation of oxygen vacancies as a function of the oxygen partial pressure. Electronic structure calculations were carried out at different strontium contents x (x=0.0, x~0.1, x~0.4, x~0.6). Progressive changes during Sr substitution were evaluated in the Density Of State (DOS). The probability densities of the gap-state wave functions were visualized in order to describe the spatial extension of the localized electron holes. The oxygen vacancy concentration, which is related to the oxygen diffusion coefficient, was calculated and coupled to a defect model in order to give at any temperature and partial oxygen pressure the defect concentration. This work will be extended to the typical LSCF material to provide some essential insights into the chemistry of this imperfect solid. [1] S. P. Jiang, International Journal of Hydrogen Energy, 2019, 44, 7448 – 7493