Bi0.5Sr0.5FeO3-δ perovskite B-site doped Ln (Nd, Sm) as cathode for high performance Co-free intermediate temperature solid oxide fuel cell

The commercialization of the Co-free solid oxide fuel cell (SOFC) cathode was hindered due to its insufficient oxygen reduction reaction (ORR) activity. In this paper, the ORR activity of the cathode material is effectively increased by doping a small amount of low-valence Ln(3+) (Nd3+, Sm3+) ions at the B-site of Fe-based perovskite Bi0.5Sr0.5FeO3- delta (BSF). Nd3+ increases the free volume (V-free) per unit cell of perovskite due to its larger ionic radius, thus increasing the oxygen vacancy concentration of Bi0.5Sr0.5Fe0.95Nd0.05O3- delta(BSFN). Compared with BSF, BSFN has greatly improved the surface oxygen exchange and volume diffusion rate through the electronic conductivity relaxation (ECR) method. At 700 degrees C, the area-specific resistance (ASR) of BSFN reached 0.062 Omega cm(-2), which was 65% lower than that of BSF (0.177 Omega cm(-2)), and the peak power density (PDD) of BSFN-based single cell reached 1.10 W cm (-2,) which was 1.7 times higher than that of BSF-based single cell (0.64 W cm (-2)). Through DRT analysis, it is concluded that BSFN can accelerate the adsorption/dissociation process of oxygen due to its higher oxygen vacancy concentration compared with BSF, so that ORR is not limited to the three-phase interface but extends to the entire cathode surface. In addition, in the 80 h long-term stability test at 600 degrees C, the BSFN-based single cell has better long-term stability because the thermal expansion coefficient of BSFN (14.1 x 10 (-6) K (-1)) is lower than that of BSF (14.4 x 10 (-6) K (-1)). In general, BSFN is expected to become a Co-free base high-performance intermediate temperature SOFC cathode.