Heteronuclear
double-atom catalysts, unlike single atom catalysts,
may change the charge density of active metal sites by introducing
another metal single atom, thereby modifying the adsorption energies
of reaction intermediates and increasing the catalytic activities.
First, density functional theory calculations are used to figure out
the best combination by modeling two transition-metal atoms from Fe,
Co, and Ni onto N-doped graphene. Generally, Fe and Co sites are highly
active for the oxygen reduction reaction (ORR) and the oxygen evolution
reaction (OER), respectively. The combination of Co and Fe to form
CoFe–N–C not only further improves the Fe’s ORR
and Co’s OER activities but also greatly enhances the Co site’s
ORR and Fe site’s OER activities. Then, we synthesize the CoFe–N–C
by a two-step pyrolysis process and find that the CoFe–N–C
exhibits exceptional ORR and OER electrocatalytic activities in alkaline
media, significantly superior to Fe–N–C and Co–N–C
and even commercial catalysts.
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