Multidimensional Hierarchical Hybrid Derived from Carbon-Based Microsphere-Supported Bimetallic Organic Frameworks Linked with Graphene Oxide for Efficient Oxygen Reduction Reaction

The rational construction and preparation of efficient, stable, and economic electrocatalysts for the oxygen reduction reaction (ORR) are necessary for fuel cells. In this work, we fabricated a porous carbon skeleton structure consisting of bimetallic organic framework (BMMOF)-derived N-doped microspheres linked with graphene oxide (GO) conducting network (denoted as UA-Co/RSC@NGF, where “UA” stands for ultrasound-assisted, “RSC” stands for resin microspheres, and “NGF” stands for N-doped graphene framework) as an efficient ORR catalyst by an ultrasound-assisted and one-step pyrolysis method. In this configuration, benefiting from the support of carbon microspheres and the strong synergistic coupling with GO, the structure of UA-Co/RSC@NGF is stabilized, and the large specific surface area enhances the density of active sites. With UA-Co/RSC@NGF as the catalyst, significant ORR properties were achieved with a high half-wave potential ( E 1/2 , 0.90 V), an onset potential ( E onset , 1.03 V), and a large limited current density (5.37 mA cm −2 ). The durability and methanol resistance of UA-Co/RSC@NGF in alkaline media outperform commercially available Pt/C. This study may open a pathway for rationally designing multidimensional composite-structured carbon-based ORR catalysts for energy-related applications.