A Superior Catalytic Air Electrode with Temperature-Induced Exsolution toward Protonic Ceramic Cells
Kang Zhu, Lijie Zhang, Nai Shi, Bingbing Qiu, Xueyu Hu, Daoming Huan, Changrong Xia, Ranran Peng, Yalin Lu
Abstract
Protonic ceramic cells merit extensive exploration, attributed to their innate capabilities for potent and environmentally benign energy conversion. In this work, a temperature-induced exsolution methodology to synthesize SrCo 0.5 Nb 0.5 O 3−δ (SCN) nanoparticles (NPs) with notably elevated activity on the surface of PrSrCo 1.8 Nb 0.2 O 6−δ (PSCN) is proposed, directly addressing the extant challenge of restrained catalytic activity prevalent in air electrode materials. In situ assessments reveal that SCN NPs commence exsolution from the matrix at temperatures surpassing 900 °C during straightforward calcination processes and maintain stability throughout annealing. Notably, the resultant SCN–PSCN interface facilitates vapor adsorption and protonation processes, which are poised to enhance surface reaction kinetics pertaining to the proton-involved oxygen reduction and evolution reaction (P-ORR and P-OER). A fuel-electrode-supported protonic ceramic cell leveraging SCN–PSCN as the air electrode manifests compelling performance, attaining a peak power density of 1.30 W·cm –2 in the fuel cell modality and a current density of 1.91 A·cm –2 at 1.3 V in the electrolysis mode, recorded at 650 °C. Furthermore, density functional theory calculations validate that the introduction of SCN NPs onto the PSCN surface conspicuously accelerates electrode reaction rates correlated with P-ORR and P-OER, by significantly mitigating energy barriers associated with surface oxygen and vapor dissociation.