Rare Earth‐Induced CoO<sub>6</sub> Octahedral Distortion in Perovskite: An Efficient Catalytic Platform for RuO<sub>2</sub>‐Catalyzed Water Oxidation
Kunhong Jiang, Yong Jiang, Zhong Liang, Chao Gu, Zhurui Shen, Yaping Du
Abstract
Abstract Rare earth (RE)‐based perovskites are considered as promising platform for oxygen evolution reaction (OER) due to their low cost and tunable structures. However, the systematic synthesis of perovskite catalysts with satisfactory performance has rarely been reported. Herein, a general synthetic protocol for RE‐substituted LaCoO 3 (RE‐LCO) perovskites is demonstrated. Particularly, after loaded with RuO 2 , the as‐prepared RuO 2 :0.2Ce‐LCO hybrid structures exhibit OER performance with a low overpotential of 135 mV at 10 mA cm −2 in 1.0 m KOH, together with remarkable long‐term operation, representing one of the most efficient and robust Ru‐based catalysts. Comprehensive experimental results indicate that the enhanced OER mechanism is attributed to the Ce‐substitution, which alters the geometric configuration of CoO 6 octahedra and generates more oxygen vacancies. Furthermore, the robust interaction between Ce‐LCO and RuO 2 stabilizes the valence state of Ru site. Theoretical calculations corroborate that Co 3d orbitals overlap with Ce 4f orbitals near the Fermi level, greatly improving the electron transfer between Co and Ce atoms.