Co and Hf co-doped BaFeO3 cathode with obviously enhanced catalytic activity and CO2 tolerance for solid oxide fuel cell

It is essential to develop efficient and stable cathode materials operated at intermediate temperature for the application of solid oxide fuel cell. In this work, BaFeO3-delta based perovskite oxide was used to explore the influence of Co and Hf co-doping on the catalytic activity and CO2 tolerance of SOFC cathode materials. Among the series materials, BaCo0.2Fe0.7Hf0.1O3-delta (BC2FHO) shows excellent catalytic activity and CO2 stability. The EIS measurement shows that the polarization resistance (R-p) of BC2FHO is similar to 0.04 Omega cm(2) at 800 degrees C. In the CO2 tolerance test, the Rp decreases to similar to 0.0435 Omega cm(2) within 1 h after removing 10% CO2. The peak power density of the single cell with BC2FHO cathode are 1010.4, 649.4, and 256.6 mW cm(-2) at 800, 700, and 600 degrees C, respectively. And the total degradation rate of the output voltage at 700 degrees C is only 0.009% h(-1). The significantly enhanced activity and stability are attributed to Co and Hf co-doping. The incorporation of Hf allows BaFeO3 to obtain a highly symmetrical cubic structure with increased oxygen ion transport channels, which is conducive to promote the oxygen reduction reaction. In addition, Hf-doping can also increase the acidity to make the material resistant to CO2. The incorporation of Co improves the concentration of oxygen vacancies, which makes BC2FHO show excellent electrochemical performance. (C) 2022 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

This study investigates the influence of Co and Hf co-doping on the performance of BaFeO3-delta based perovskite oxide as cathode materials for solid oxide fuel cells (SOFC). The results show that the co-doped material exhibits excellent catalytic activity, CO2 stability, and electrochemical performance.