Optimization of La Sr-0.6 (0.4) Co (0.2) Fe (0.8) O (3)-alpha - Ba(Ce Zr-0.6 (0.4)) (0.9) Y (0.1) O (3)-delta cathode composition for proton ceramic fuel cell application

Composite cathodes consisting of different compositional ratios of La Sr-0.6 (0.4) Co (0.2) Fe (0.8) O (3-alpha) (LSCF) and Ba(Ce (0.6) Zr (0.4)) Y-0.9 O-0.1 (3-delta) (BCZY64), namely 100LSCF:0BCZY64 (L10B0), 70LSCF:30BCZY64 (L7B3), 50LSCF:50BCZY64 (L5B5) and 30LSCF:70BCZY64 (L3B7) were prepared via wet chemistry method. The symmetrical cell with a configuration of electrode|BCZY64|electrodewas fabricated using dry-pressingmethod for the electrolyte substrate and spin-coating technique for the cathode layer. The proton conduction in the composite cathode increases as the amount of proton-conducting phase increases as verified by the water uptake measurement performed via thermogravimetric analysis. The thickness of the composite cathode layer is about 15 mu m as observed by a scanning electron microscope and exhibits a well-connected particle network with sufficient porosity for oxidant diffusion (20-30%). The electrochemical performance of the symmetrical cell was investigated by electrochemical impedance spectroscopy in humidified air. The area-specific resistance (ASR) values of the tested cathodes follow the order of L7B3 < L10B0 < L5B5 < L3B7 and are 0.07 < 0.24 < 0.30 < 0.52 W center dot cm(2) at 700 degrees C, respectively. The correlation between the cathode performance and cathode composition was investigated and the corresponding mechanism was systematically postulated.