Crystallinity-dependent structural evolution of CoS2 catalysts for enhanced oxygen evolution reaction
Nan Zhang, Yang Hu, Zhuang Zhang, Chao Wu, Jiamin Zhu, Yuqing Zhang, Wei Shen, Shanshan Wu, Shibo Xi, Li An, Pinxian Xi, Chun‐Hua Yan
Abstract
Transition metal sulfides (TMSs) are promising catalysts for water oxidation due to their unique electronic properties, but their application is limited by structural instability during the oxygen evolution reaction (OER). The specific mechanisms by which crystallinity variations in TMSs influence their structural evolution and catalytic performance remain poorly understood. Here, we investigate the structural evolution of CoS2 catalysts with varying crystallinities and their effect on the OER. In-situ characterization and density functional theory (DFT) calculations reveal that lower crystallinity enables rapid equilibrium among surface sulfur-oxygen exchange, metal site activation, and oxygen intermediate evolution, enhancing the transformation of bulk phase into small amounts of sulfur-stabilized oxyhydroxide and improving OER performance. Conversely, moderate crystallinity leads to self-corrosion and progressive structure collapse from the exterior inward, resulting in deactivation. This work highlights the potential of crystallinity control in optimizing the electronic states and catalytic behavior of water oxidation catalysts. This work investigates crystallinity-dependent structural evolution mechanisms of CoS2 during the oxygen evolution reaction, showing that CoS2 with lower crystallinity enhances the transformation of the bulk phase into sulfur-stabilized oxyhydroxide, improving performance.