AI Article Synopsis
- Fe-N-C single-atomic metal site catalysts (SACs) are being explored as alternatives to platinum-based catalysts for oxygen reduction reactions in fuel cells.
- Researchers aim to enhance the efficiency of these catalysts by modifying the electronic structure of their active sites, particularly through the use of heteroatom doping.
- The study introduces chlorine as a near-range coordinator to improve the Fe-N active center, resulting in a catalyst (FeNCl SAC) that shows higher ORR activity compared to traditional FeN SAC, supported by theoretical calculations and experimental results.
Article Abstract
Fe-N-C single-atomic metal site catalysts (SACs) have garnered tremendous interest in the oxygen reduction reaction (ORR) to substitute Pt-based catalysts in proton exchange membrane fuel cells. Nowadays, efforts have been devoted to modulating the electronic structure of metal single-atomic sites for enhancing the catalytic activities of Fe-N-C SACs, like doping heteroatoms to modulate the electronic structure of the Fe-N active center. However, most strategies use uncontrolled long-range interactions with heteroatoms on the Fe-N substrate, and thus the effect may not precisely control near-range coordinated interactions. Herein, the chlorine (Cl) is used to adjust the Fe-N active center via a near-range coordinated interaction. The synthesized FeNCl SAC likely contains the FeNCl active sites in the carbon matrix. The additional Fe-Cl coordination improves the instrinsic ORR activity compared with normal FeN SAC, evidenced by density functional theory calculations, the measured ORR half-wave potential (, 0.818 V), and excellent membrane electrode assembly performance.
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| http://dx.doi.org/10.1021/acsnano.2c06459 | DOI Listing |
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