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Atomic Structure Modification of Fe‒N‒C Catalysts via Morphology Engineering of Graphene for Enhanced Conversion Kinetics of Lithium–Sulfur Batteries.

Authors :
Kim, Jiheon
Kim, Seong‐Jun
Jung, Euiyeon
Mok, Dong Hyeon
Paidi, Vinod K.
Lee, Jaewoo
Lee, Hyeon Seok
Jeoun, Yunseo
Ko, Wonjae
Shin, Heejong
Lee, Byoung‐Hoon
Kim, Shin‐Yeong
Kim, Hyunjoong
Kim, Ji Hwan
Cho, Sung‐Pyo
Lee, Kug‐Seung
Back, Seoin
Yu, Seung‐Ho
Sung, Yung‐Eun
Hyeon, Taeghwan
Source :
Advanced Functional Materials; 5/9/2022, Vol. 32 Issue 19, p1-11, 11p
Publication Year :
2022

Abstract

Single‐atom M‒N‒C catalysts have attracted tremendous attention for their application to electrocatalysis. Nitrogen‐coordinated mononuclear metal moieties (MNx moities) are bio‐inspired active sites that are analogous to various metal‐porphyrin cofactors. Given that the functions of metal‐porphyrin cofactors are highly dependent on the local coordination environments around the mononuclear active site, engineering MNx active sites in heterogeneous M‒N‒C catalysts would provide an additional degree of freedom for boosting their electrocatalytic activity. This work presents a local coordination structure modification of FeN4 moieties via morphological engineering of graphene support. Introducing highly wrinkled structure in graphene matrix induces nonplanar distortion of FeN4 moieties, resulting in the modification of electronic structure of mononuclear Fe. Electrochemical analysis combined with first‐principles calculations reveal that enhanced electrocatalytic lithium polysulfide conversion, especially the Li2S redox step, is attributed to the local structure modified FeN4 active sites, while increased specific surface area also contributes to improved performance at low C‐rates. Owing to the synergistic combination of atomic‐level modified FeN4 active sites and morphological advantage of graphene support, Fe‒N‒C catalysts with wrinkled graphene morphology show superior lithium–sulfur battery performance at both low and high C‐rates (particularly 915.9 mAh g−1 at 5 C) with promising cycling stability. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
1616301X
Volume :
32
Issue :
19
Database :
Complementary Index
Journal :
Advanced Functional Materials
Publication Type :
Academic Journal
Accession number :
156769554
Full Text :
https://doi.org/10.1002/adfm.202110857