Abstract
Co single-atom catalysts show significant potential in enhancing oxygen evolution reaction (OER) efficiency, crucial for advancing renewable energy technologies. However, their performance is constrained by a single active site, making it challenging for traditional OER pathways to surpass theoretical overpotential limits. By focusing on dual active sites, this study systematically investigates the structural evolution and catalytic performance of Co based double atom catalysts using density functional theory. Co as the primary metal (M1), pairs with 15 different transition metals (M2) to create bimetallic catalysts. The formation energies, binding energies, and Gibbs free energy changes along four potential OER reaction pathways are calculated to assess the stability and activity of these catalysts. The results show enhanced catalytic performance along path II (H₂O → *OH → *2OH → *OOH → O₂) for Co-Ni, Co-Cu, Co-Pd, and Co-Pt catalysts. This improvement stems from synergistic interactions between metal atoms, bypassing high-energy barriers in traditional pathways. Notably, the d-band centers of Cu, Pd, and Pt near the Fermi level boost electron transfer. Co provides stable adsorption sites, optimizing the conversion of intermediates. This study advances understanding of the reaction mechanism and guides the development of more efficient catalysts.
Published Version
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