Defect‐Engineered Co<sub>3</sub>O<sub>4</sub>@Nitrogen‐Deficient Graphitic Carbon Nitride as an Efficient Bifunctional Electrocatalyst for High‐Performance Metal‐Air Batteries
Wenhao Tang, Kewei Teng, Wengai Guo, Fan Gu, Boya Li, Ruiyu Qi, Ruiping Liu, Yuyin Lin, Miaomiao Wu, Yihuang Chen
Abstract
Abstract The ability to craft high‐efficiency and non‐precious bifunctional oxygen catalysts opens an enticing avenue for the real‐world implementation of metal‐air batteries (MABs). Herein, Co 3 O 4 encapsulated within nitrogen defect‐rich g‐C 3 N 4 (denoted Co 3 O 4 @ND‐CN) as a bifunctional oxygen catalyst for MABs is prepared by graphitizing the zeolitic imidazolate framework (ZIF)‐67@ND‐CN. Co 3 O 4 @ND‐CN possesses superb bifunctional catalytic performance, which facilitates the construction of high‐performance MABs. Concretely, the rechargeable zinc‐air battery based on Co 3 O 4 @ND‐CN shows a superior round‐trip efficiency of ≈60% with long‐term durability (over 340 cycles), exceeding the battery with the state‐of‐the‐art noble metals. The corresponding lithium‐oxygen battery using Co 3 O 4 @ND‐CN exhibits an excellent maximum discharge/charge capacity (9838.8/9657.6 mAh g −1 ), an impressive discharge/charge overpotential (1.14 V/0.18 V), and outstanding cycling stability. Such compelling electrocatalytic processes and device performances of Co 3 O 4 @ND‐CN originate from concurrent compositional (i.e., defect‐engineering) and structural (i.e., wrinkled morphology with abundant porosity) elaboration as well as the well‐defined synergy between Co 3 O 4 and ND‐CN, which produce an advantageous surface electronic environment corroborated by theoretical modeling. By extension, a rich diversity of other metal oxides@ND‐CN with adjustable defects, architecture, and enhanced activities may be rationally designed and crafted for both scientific research on catalytic properties and technological development in renewable energy conversion and storage systems.