Rechargeable Zn–air batteries have drawn great attention over the past decade, but their further development will require efficient bifunctional electrocatalysts to drive the sluggish cathodic reactions. Although a single-atom catalyst with maximum utilization per metal atom shows great promise, its catalytic performance is still far from satisfactory. Here we tackle this challenge by introducing a P–O bond to update the intrinsic activity of a single-atom site and thus reduce the reaction overpotential of the Zn–air battery. The critical role of the P–O bond in producing a favorable surface electronic environment of the single-atom metal site and improving its catalytic activity is identified with density functional theory simulations. The P–O-doped, atomically dispersed catalyst is shown experimentally to deliver excellent bifunctional performance, with a remarkable half-wave potential of 0.89 V versus reversible hydrogen electrode (vs RHE) for oxygen reduction reaction and a reversible oxygen electrode index of 0.74 V, exceeding those of most reported nonprecious metal catalysts. When subjected to practical application, both aqueous and all-solid-state Zn–air batteries illustrate superior power density and robust cyclic performance, confirming their potential feasibility in next-generation electronic devices.
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