Abstract
The sluggish kinetics and poor stability of the oxygen reduction reaction (ORR) remain the primary bottleneck for achieving high performance in protonic ceramic fuel cells (PCFCs) at intermediate temperatures (400-650°C). In this work, a Pr-based nanocomposite cathode comprised of simple perovskite phase (PrNi(0.7)Co(0.3)O(3-δ)) and Ruddlesden-Popper phase (Co-doped Pr(4)Ni(3)O(10+δ)) is developed. Although PrNi(0.7)Co(0.3)O(3-δ) solely stands as a good cathode with facile proton transfer, combining the superior catalytic activity against oxygen on the Ruddlesden-Popper phase boosts the ORR performance further. The designed nanocomposite cathode outperforms the simple perovskite cathode, attributed to enhanced oxygen absorption and surface diffusion with the Ruddlesden-Popper phase. A precursor-based cathode deposition technique is also developed to achieve cathode grain sizes of ∼100 nm. A single cell with the nanocomposite cathode delivers a peak power density of 1.38 W cm(-2) at 650°C, among the highest in reported PCFCs with Pr-based cathodes, with a small degradation rate of 0.145 mV h(-1) during 250 h stability test. Further investigation of cathode-electrolyte interface revealed interfacial PrO(2) phase formation, promoted by abundant Pr(6)O(11) in the nanocomposite precursor powder, thereby improving both ohmic resistance and stability. These findings highlight the effectiveness of the nanocomposite cathode and underscore its advantages on interfacial properties.