Abstract

Abstract It is important to tune the coordination configuration of dual‐atom catalyst (DAC), especially in the first coordination sphere, to render high intrinsic catalytic activities for oxygen reduction/evolution reactions (ORR/OER). Herein, a type of atomically dispersed and boron‐coordinated DAC structure, namely, FeN 4 B‐NiN 4 B dual sites, is reported. In this structure, the incorporation of boron into the first coordination sphere of FeN 4 /NiN 4 atomic sites regulates its geometry and electronic structure by forming “Fe‐B‐N” and “Ni‐B‐N” bridges. The FeN 4 B‐NiN 4 B DAC exhibits much enhanced ORR and OER property compared to the FeN 4 ‐NiN 4 counterparts. Density functional theory calculations reveal that the boron‐induced charge transfer and asymmetric charge distributions of the central Fe/Ni atoms optimize the adsorption and desorption behavior of the ORR/OER intermediates and reduce the activation energy for the potential‐determining step. Zinc‐air batteries employing the FeN 4 B‐NiN 4 B cathode exhibit a high maximum power density (236.9 mW cm −2 ) and stable cyclability up to 1100 h. The result illustrates the pivotal role of the first‐coordination sphere of DACs in tuning the electrochemical energy conversion and storage activities.