Oxophilic Sites Mediated Dynamic Oxygen Replenishment to Stabilize Lattice Oxygen Catalysis in Acidic Water Oxidation
Shaoxiong Li, Sheng Zhao, Sung‐Fu Hung, Liming Deng, Luqi Wang, Fuke Shi, Ao Dong, Ying Zhang, Tsung‐Yi Chen, Feng Hu, Linlin Li, Seeram Ramakrishna, Yuping Wu, Shiling Peng
Abstract
Developing efficient and durable catalysts for the oxygen evolution reaction (OER) in acidic media is essential for advancing proton exchange membrane water electrolysis (PEMWE). However, catalyst instability caused by lattice oxygen (O L ) depletion and metal dissolution remains a critical barrier. Here, we propose an oxophilic-site-mediated dynamic oxygen replenishment mechanism (DORM), in which O L actively participates in O–O bond formation and is continuously refilled by water-derived species. Oxophilic dopants modulate the local electronic structure, lower the energy barrier for oxygen vacancy healing, and reorganize the interfacial hydrogen-bond network to enhance water mobility, orientation, and proton accessibility, collectively promoting water dissociation and stabilizing O L catalysis. The optimized catalyst achieves a low overpotential of 289 mV and exceptional durability, operating continuously for 650 h at 10 mA cm –2 in acidic electrolyte and maintaining stable performance for 280 h at 1 A cm –2 in a PEMWE. This work establishes a mechanistic framework for dynamic O L redox and provides a rational strategy for designing robust, noble-metal-free acidic OER electrocatalysts.