Modulating the electronic structure of atomically dispersed Fe-Pt dual-site catalysts for efficient oxygen reduction reactions

Atomically dispersed catalysts, with a high atomic dispersion of active sites, are efficient electrocatalysts. However, their unique catalytic sites make it challenging to improve their catalytic activity further. In this study, an atomically dispersed Fe-Pt dual-site catalyst (FePtNC) has been designed as a high-activity catalyst by modulating the electronic structure between adjacent metal sites. The FePtNC catalyst showed significantly better catalytic activity than the corresponding single-atom catalysts and metal-alloy nanocatalysts, with a half-wave potential of 0.90 V for the oxygen reduction reaction. Moreover, metal-air battery systems fabricated with the FePtNC catalyst showed peak power density values of 90.33 mW cm(-2) (Al-air) and 191.83 mW cm(-2) (Zn-air). By combining experiments and theoretical simulations, we demonstrate that the enhanced catalytic activity of the FePtNC catalyst can be attributed to the electronic modulation effect between adjacent metal sites. Thus, this study presents an efficient strategy for the rational design and optimization of atomically dispersed catalysts.

Automated summary

In this study, an atomically dispersed Fe-Pt dual-site catalyst (FePtNC) with high catalytic activity has been designed by modulating the electronic structure between adjacent metal sites. The FePtNC catalyst exhibited significantly better catalytic activity than single atom catalysts and metal-alloy nanocatalysts, with a half-wave potential of 0.90 V for the oxygen reduction reaction. Metal-air battery systems fabricated with the FePtNC catalyst showed peak power density values of 90.33 mW cm(-2) (Al-air) and 191.83 mW cm(-2) (Zn-air). The enhanced catalytic activity of the FePtNC catalyst is attributed to the electronic modulation effect between adjacent metal sites, which was demonstrated through experiments and theoretical simulations.