Aligned d-orbital energy level of dual-atom sites catalysts for oxygen reduction reaction in anion exchange membrane fuel cells
Youze Zeng, Xue Wang, Qi Wei, Changpeng Liu, Lanlu Lu, Meiling Xiao, Kai Li, Fei Xiao, Minhua Shao, Wei Xing, Jianbing Zhu
Abstract
The inherent scaling relationships between adsorption energies of oxygen-containing intermediates impose an intrinsic limitation on the maximum oxygen reduction reaction (ORR) activity, which represents one of the bottlenecks for the practical application of anion exchange membrane fuel cells (AEMFCs). To address this challenge, we align the 3dz2 orbital energy levels of Fe and Co to selectively customize the dissociative ORR pathway without the formation of OOH* intermediates, circumventing the conventional OH*-OOH* scaling relations. This rational design is achieved by atomic phosphorus(P) substitution, which not only optimizes orbital matching towards O-O cis-bridge adsorption, but also stabilizes the spontaneously adsorbed OH ligand as an electronic modifier. Due to these attributes, the well-designed FeCo-N/P-C catalyst demonstrates ORR performance with a current density of 251 mA·cm-2 at 0.9 ViR-free under 1.5 bar H2-O2, showing a competitive performance with state-of-the-art Pt-free electrocatalysts and meeting the 2025 DOE target (44 mA·cm-2). More importantly, the peak power density reaches as high as 0.805 W·cm-2 under 1.5 bar H2-air with negligible degradation observed over 10,000 cycles of voltage accelerated stress testing. This work offers a highly competitive electrocatalyst for AEMFCs and opens an effective avenue to bypass the constraints of linear scaling relations for ORR and beyond. The inherent scaling relationships among the adsorption energies of intermediates limit the efficiency of oxygen electrocatalysis. Here, a dual-atom catalyst with aligned orbital energy level is developed, driving the dissociative pathway to bypass scaling relationships towards enhanced performance.