Tuning Electrocatalytic Water Oxidation Activity: Insights from the Active‐Site Distance in LnCu6 Clusters

Atomically precise metal clusters serve as a unique model for unraveling the intricate mechanism of the catalytic reaction and exploring the complex relationship between structure and activity. Herein, three series of water‐soluble heterometallic clusters LnCu6, abbreviated as LnCu6‐AC (Ln = La, Nd, Gd, Er, Yb; HAC = acetic acid), LnCu6‐IM (Ln = La and Nd; IM = Imidazole), and LnCu6‐IDA (Ln = Nd; H2IDA = Iminodiacetic acid) are presented, each featuring a uniform metallic core stabilized by distinct protected ligands. Crystal structure analysis reveals a triangular prism topology formed by six Cu2+ ions around one Ln3+ ion in LnCu6, with variations in Cu···Cu distances attributed to different ligands. Electrocatalytic oxygen evolution reaction (OER) shows that these different LnCu6 clusters exhibit different OER activities with remarkable turnover frequency of 135 s−1 for NdCu6‐AC, 79 s−1 for NdCu6‐IM and 32 s−1 for NdCu6‐IDA. Structural analysis and Density Functional Theory (DFT) calculations underscore the correlation between shorter Cu···Cu distances and improves OER catalytic activity, emphasizing the pivotal role of active‐site distance in regulating electrocatalytic OER activities. These results provide valuable insights into the OER mechanism and contribute to the design of efficient homogeneous OER electrocatalysts. A series of water‐soluble LnCu6 clusters featuring a uniform metallic core but distinct ligands demonstrate the significant impact of manipulating active site distance on enhancing homogeneous electrocatalytic water oxidation.