催化作用
双层
表面工程
电催化剂
材料科学
化学工程
纳米技术
多孔性
活动站点
氧还原反应
化学
氧气
电化学能量转换
碳纤维
能量转换
分子工程
膜
脂质双层
密度泛函理论
电子结构
无机化学
电化学
氧化还原
质子交换膜燃料电池
单层
表面能
析氧
燃料电池
储能
化学物理
作者
Yu Chen,Yan Meng,Mengke Zou,Yuxin Xiang,Hong Zhong,Scott P. Beckman,Yuehe Lin,Wenbo Zhao,Peng-Fei Xie,Jian Peng,Shi-Yong Zhao,Lili Zhang,Peng-Xiang Hou,Chang Liu,Jin-Cheng Li
出处
期刊:ACS Catalysis
[American Chemical Society]
日期:2026-03-31
卷期号:16 (8): 7495-7505
标识
DOI:10.1021/acscatal.5c09128
摘要
Challenges in rationally fabricating high-performance Fe–N/C catalysts for oxygen reduction reaction (ORR)-related energy devices give strong motivation to modulate the electronic structure of surface Fe active centers. Herein, a molecular engineering strategy is developed to prepare an Fe–N/C catalyst with surface enrichment of N-bridged bilayer FeN4 (N4Fe–N–FeN4) active sites. A dual-Fe-atom nanocluster, constructed of [Fe(CN)6]3– coupled with Fe3+–N4 in hemin by molecular interaction, is used to transform into the bilayer N4Fe–N–FeN4 site on N-doped porous carbon by confined pyrolysis. Theoretical calculations reveal that N-bridged sublayer FeN4 modulates the electronic structure of the surface-layer FeN4 site and therefore decreases the ORR energy barrier at the surface Fe active center. Thus, the resulting catalyst shows ORR performance with half-wave potentials of 0.815 V under acidic conditions and 0.890 V in alkaline media. More importantly, ORR-related energy devices are assembled, exhibiting performance such as high peak power densities of 760 mW cm–2 for a H2–O2 fuel cell and 354 mW cm–2 for a Zn–O2 battery. This study not only provides a strategy for developing high-performance next-generation catalysts but also elucidates insights into the electrocatalytic mechanisms, contributing to advances in energy devices.
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