Generalized Encapsulations of ZIF‐Based Fe–N–C Catalysts with Controllable Nitrogen‐Doped Carbon for Significantly‐Improved Stability Toward Oxygen Reduction Reaction

The vigorous development of efficient platinum group metal‐free catalysts is considerably important to facilitate the universal application of proton exchange membrane fuel cells. Although nitrogen‐coordinated atomic iron intercalated in carbon matrix (Fe–N–C) catalysts exhibit promising catalytic a...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2023-06, Vol.19 (25), p.e2207671-n/a
Main Authors: Wu, Yongkang, Li, Xiaoke, Hua, Kang, Duan, Xiao, Ding, Rui, Rui, Zhiyan, Cao, Feng, Yuan, Mengchen, Li, Jia, Liu, Jianguo
Format: Article
Language:English
Subjects:
Carbon
Catalysts
Catalytic activity
Chemical reduction
Coating
Controllability
Core loss
Corrosion effects
Discharge
Fe–N–C catalysts
Fuel cells
Nanotechnology
Nitrogen
N–C coating
Oxygen reduction reactions
Platinum metals
Proton exchange membrane fuel cells
stability
Synergistic effect
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Summary:The vigorous development of efficient platinum group metal‐free catalysts is considerably important to facilitate the universal application of proton exchange membrane fuel cells. Although nitrogen‐coordinated atomic iron intercalated in carbon matrix (Fe–N–C) catalysts exhibit promising catalytic activity, the performance in fuel cells, especially the short lifetime, remains an obstacle. Herein, a highly‐active Fe–N–C catalyst with a power density of >1 w cm‐2 and prolonged discharge stability with a current density of 357 mA cm‐2 after 40 h of constant voltage discharge at 0.7 V in H2–O2 fuel cells using a controllable and efficient N–C coating strategy is developed. It is clarified that a thicker N–C coating may be more favorable to enhance the stability of Fe–N–C catalysts at the expense of their catalytic activity. The stability enhancement mechanism of the N–C coating strategy is proven to be the synergistic effect of reduced carbon corrosion and iron loss. It is believed that these findings can contribute to the development of Fe–N–C catalysts with high activity and long lifetimes. Development of highly‐catalytic and long‐term stable Fe–N–C catalyst using a controllable and efficient N–C coating strategy. The correlation between the thickness of N–C coatings and electrochemical performance is investigated. The stability improvement mechanism of N–C coating is identified to reduce carbon corrosion and iron leaching.
ISSN:1613-6810
1613-6829
DOI:10.1002/smll.202207671