碳纤维
氮气
材料科学
二茂铁
多孔性
化学
无机化学
结晶学
金属
硫黄
固溶体
化学工程
星团(航天器)
光谱学
一氧化碳
作者
Tao Wu,Jie Yin,Shufei Zhu,黄海,Yiming Xie,Canzhong Lu
摘要
ABSTRACT Achieving both high activity and metal loading of atomically dispersed metal sites in M─N─C catalysts remain a formidable challenge. Herein, we employ the macrocyclic supramolecule cucurbit[7]uril (CB[7]) as a nanocage precursor and ferrocene (Fc) as a metal source, respectively. Through spontaneous host–guest self‐assembly, an angstrom‐level space‐confined precursor (Fc@CB[7]) was constructed, providing a well‐defined molecular scaffold for oxygen electrocatalysts. The resulting Fc@CB[7] complex exhibits a cage‐with‐lid geometry, endowing it with the structural characteristics of a metal monatomic precursor. Upon coating the Fc@CB[7] complex with ternary eutectic salts (NaCl, KCl, ZnCl 2 , named TESs) and subjecting it to pyrolysis, we obtained a novel oxygen electrocatalyst, denoted Fe AC ─Fe SA /N─CBC 0.7 , featuring coexisting Fe atomic clusters and Fe single atoms. The deliberately designed Fe AC ─Fe SA /N─CBC 0.7 catalyst delivers a remarkable half‐wave potential ( E 1/2 ) of 0.915 V and outstanding Zn–air battery (ZAB) performance. Density functional theory (DFT) calculations identify the presence of Fe 7 clusters that modulate the local electronic configuration of Fe─N 4 sites and weaken *OH adsorption, thereby accelerating the oxygen reduction reaction (ORR) kinetics. This work not only paves a way between supramolecular chemistry and electrochemistry but also provides fundamental insights into the structure–activity relationship of Fe AC ─Fe SA /N─CBC 0.7 for ORR.
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