Integration of Morphology and Electronic Structure Modulation on Atomic Iron‐Nitrogen‐Carbon Catalysts for Highly Efficient Oxygen Reduction

Atomic transition‐metal‐nitrogen‐carbon catalysts (M‐N‐Cs) hold great promise as Pt‐group‐metal‐free candidates for electrochemical reactions, yet their rational design and controllable synthesis remain fundamental challenges. Here, the molten‐salts mediated pyrolysis is demonstrated to be an effect...

Full description

Saved in:
Bibliographic Details
Published in:Advanced functional materials 2022-01, Vol.32 (2), p.n/a
Main Authors: Xin, Cuncun, Shang, Wenzhe, Hu, Jinwen, Zhu, Chao, Guo, Jingya, Zhang, Jiangwei, Dong, Haopeng, Liu, Wei, Shi, Yantao
Format: Article
Language:English
Subjects:
Atomic structure
Carbon
Catalysis
Chemical reactions
Dechlorination
Electrocatalysts
Electronic structure
halogen coordination
Iron
Materials science
Mathematical analysis
Modulation
molten‐salts strategy
Morphology
Nitrogen
oxygen reduction reaction
Oxygen reduction reactions
Pyrolysis
Single atom catalysts
X‐ray absorption spectroscopy
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Atomic transition‐metal‐nitrogen‐carbon catalysts (M‐N‐Cs) hold great promise as Pt‐group‐metal‐free candidates for electrochemical reactions, yet their rational design and controllable synthesis remain fundamental challenges. Here, the molten‐salts mediated pyrolysis is demonstrated to be an effective and facile strategy for simultaneous morphology and electronic structure modulation of prototypical Fe‐N‐C materials, which functions as efficient oxygen reduction electrocatalysts. Taking advantage of the strong polarity and salt templating effects, the as‐obtained Fe‐N/C‐single atom catalyst (SAC) possesses hierarchical porous nanosheet morphology with an impressive specific surface area of 2237 m2 g−1 and unique FeN4Cl moieties as isolated active centers. The Fe‐N/C‐SAC delivers remarkable alkaline oxygen reduction reaction (ORR) activity with a half‐wave potential of 0.91 V and record kinetic current density up to 55 mA cm−2, outperforming the benchmark Pt/C. By virtue of dechlorination treatment, it is experimentally identified that the enhanced ORR activities are essentially governed by the axially bound Cl. Theoretical calculations rationalize this finding and demonstrate that the well‐defined fivefold‐coordinated configuration accelerates 4e− pathway kinetics through near‐optimal adsorption of the *OH intermediates and tunes the potential determining step from *OH reduction to *OOH formation. This study provides fundamental insights into the coordination‐engineered strategy in single‐atom catalysis. Atomic‐site halogenation and hierarchical porosity engineering on M‐N‐Cs catalysts are achieved through a controllable molten‐salts mediated pyrolysis method to boost the sluggish oxygen reduction kinetics. Fe‐N/C‐single atom catalyst demonstrates a remarkable alkaline oxygen reduction reaction activity with a half‐wave potential of 0.91 V and record kinetic current density up to 55 mA cm−2, outperforming the benchmark Pt/C.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202108345