AI Article Synopsis
- Atomic iron (Fe) in nitrogen-doped carbon (FeNC) catalysts shows promise as a substitute for platinum-group metals in fuel cells, but challenges in synthesis and stability persist.
- A new two-step synthesis method enhances Fe-loading and electrochemical activity, yet achieving adequate porosity for active site exposure remains difficult.
- This study introduces a highly porous support that boosts Fe utilization to 52% and reveals stable single-atom Fe configurations, supported by advanced spectroscopy and theoretical calculations.
Article Abstract
Atomic Fe in N-doped carbon (FeNC) electrocatalysts for oxygen (O ) reduction at the cathode of proton exchange membrane fuel cells are the most promising alternative to platinum-group-metal catalysts. Despite recent progress on atomic FeNC O reduction, their controlled synthesis and stability for practical applications remain challenging. A two-step synthesis approach has recently led to significant advances in terms of Fe-loading and mass activity; however, the Fe utilization remains low owing to the difficulty of building scaffolds with sufficient porosity that electrochemically exposes the active sites. Herein, this issue is addressed by coordinating Fe in a highly porous nitrogen-doped carbon support (≈3295 m g ), prepared by pyrolysis of inexpensive 2,4,6-triaminopyrimidine and a Mg salt active site template and porogen. Upon Fe coordination, a high electrochemical active site density of 2.54 × 10 sites g and a record 52% FeN electrochemical utilization based on in situ nitrite stripping are achieved. The Fe single atoms are characterized pre- and post-electrochemical accelerated stress testing by aberration-corrected high-angle annular dark field scanning transmission electron microscopy, showing no Fe clustering. Moreover, ex situ X-ray absorption spectroscopy and low-temperature Mössbauer spectroscopy suggest the presence of penta-coordinated Fe sites, which are further studied by density functional theory calculations.
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