BaFe12O19 Functional Porous Carbon Nanocomposite as an Electrocatalyst of the Oxygen Reduction Reaction

Abstract

AbstractIt is crucial to develop a non‐precious metal catalyst with high efficiency, affordable cost, and minimal environmental impact for conducting research on the oxygen reduction reaction (ORR) in fuel cells. In this study, BaFe12O19 functional porous carbon (BaFe12O19/PC) nanocomposite was successfully prepared using Fe2O3, BaCO3 and glucose as precursors. Meanwhile, the BaFe12O19/PC catalyst‐modified glassy carbon electrode, carbon rod, and Hg/HgO electrode were used as the working electrode, counter electrode, and reference electrode, respectively, to investigate the electrochemical behavior. The uniform distribution of nano‐scale BaFe12O19 particles in a porous carbon framework was confirmed by field emission scanning electron microscopy characterization. In addition, a double‐layer interface (Fe/Fe3C) was formed between the porous carbon and the nano‐sized BaFe12O19 particles. Fe/Fe3C has a synergistic effect with C, facilitating the migration and transfer of electrons from BaFe12O19 to porous carbon. The BaFe12O19/PC nanocomposite exhibited a four‐electron pathway for electrocatalytic kinetics, showcasing a significantly elevated half‐wave potential of 0.77 V, an impressively reduced Tafel slope of 84.95 mV/dec, and exceptional tolerance towards methanol. It is important to highlight that the BaFe12O19/PC nanocomposite not only possess high catalytic activity for oxygen reduction reactions (ORR), but also demonstrate excellent stability. Consequently, this synthesized BaFe12O19/PC nanocomposite hold promising prospects as cost‐effective and efficient catalysts in fuel cell applications.