A Generalized Coordination Engineering Strategy for Single-Atom Catalysts toward Efficient Hydrogen Peroxide Electrosynthesis.

Designing non-noble metal single-atom catalysts (M-SACs) for two-electron oxygen reduction reaction (2e-ORR) is attractive for the hydrogen peroxide (H ₂ O ₂ ) electrosynthesis, in which the coordination configuration of the M-SACs essentially affects the reaction activity and product selectivity. Though extensively investigated, a generalized coordination engineering strategy has not yet been proposed, which fundamentally hinders the rational design of M-SACs with optimized catalytic capabilities. Herein, a generalized coordination engineering strategy is proposed for M-SACs toward H ₂ O ₂ electrosynthesis via introducing heteroatoms (e.g., oxygen or sulfur atoms) with higher or lower electronegativity than nitrogen atoms into the first sphere of metal-N ₄ system to tailor their electronic structure and adjust the adsorption strength for ^* OOH intermediates, respectively, thus optimizing their electrocatalytic capability for 2e-ORR. Specifically, the (O, N)-coordinated Co SAC (Co-N ₃ O) and (S, N)-coordinated Ni SAC (Ni-N ₃ S) are precisely synthesized, and both present superior 2e-ORR activity (E _onset : ≈0.80 V versus RHE) and selectivity (≈90%) in alkaline conditions compared with conventional Co-N ₄ and Ni-N ₄ sites. The high H ₂ O ₂ yield rates of 14.2 and 17.5 moL g ^-1  h ^-1 and long-term stability over 12 h are respectively achieved for Co-N ₃ O and Ni-N ₃ S. Such favorable 2e-ORR pathway of the catalysts is also theoretically confirmed by the kinetics simulations.
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