materials, [2] and their coupled composites. [3] Among them, TM singleatom catalysts (SACs) have recently emerged as a new type of frontier materials with high activity, stability, and selectivity, rendering the great potential for diverse catalytic systems. [4] The unique electronic structure, maximized atomutilization efficiency, and unsaturated coordination bonds of the active centers in SACs contribute to the enhanced performance. [5] Moreover, recent investigations have demonstrated that the introduction of secondary metal atoms can further enhance the activity of SACs, indicating the promising development of dual-metal SACs. [6] Nevertheless, on the one hand, there is a serious lack of effective strategies to achieve the atomic control of targeted reactive sites comprising binary metal atoms; on the other hand, the identification of the diatomic structure in dual-metal SACs and the deeper functional mechanism of bimetallic atoms for synergistic catalysis are still in their infancy.Owing to the increasing concerns from energy and environmental issues, growing attention has been paid on developing sustainable energy conversion and storage technologies, such as water-splitting electrolyzers, fuel cells, metal-air batteries, etc. [7] However, the sluggish kinetics of oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) on the electrodes has been proven to With the inspiration of developing bifunctional electrode materials for reversible oxygen electrocatalysis, one strategy of heteroatom doping is proposed to fabricate dual metal single-atom catalysts. However, the identification and mechanism functions of polynary single-atom structures remain elusive. Atomically dispersed binary Co-Ni sites embedded in N-doped hollow carbon nanocubes (denoted as CoNi-SAs/NC) are synthesized via proposed pyrolysis of dopamine-coated metalorganic frameworks. The atomically isolated bimetallic configuration in CoNi-SAs/NC is identified by combining microscopic and spectroscopic techniques. When employing as oxygen electrocatalysts in alkaline medium, the resultant CoNi-SAs/NC hybrid manifests outstanding catalytic performance for bifunctional oxygen reduction/evolution reactions, boosting the realistic rechargeable zinc-air batteries with high efficiency, low overpotential, and robust reversibility, superior to other counterparts and state-of-the-art precious-metal catalysts. Theoretical computations based on density functional theory demonstrate that the homogenously dispersed single atoms and the synergistic effect of neighboring Co-Ni dual metal center can optimize the adsorption/desorption features and decrease the overall reaction barriers, eventually promoting the reversible oxygen electrocatalysis. This work not only sheds light on the controlled synthesis of atomically isolated advanced materials, but also provides deeper understanding on the structure-performance relationships of nanocatalysts with multiple active sites for various catalytic applications.To date, large numbers of low cost and efficie...