化学
催化作用
氧气
还原(数学)
无机化学
氧还原反应
产量(工程)
氧化还原
化学还原
反应条件
反应机理
氧化还原
有机化学
氧还原
反应中间体
悠氧
核化学
作者
Shu-Hu Yin,Fei-Fan Dai,Guang Li,Ming-Yu Zhou,Ming Gong,Ting Zhu,Huan Huang,Yanxia Jiang,Jun Xu,Shi-Gang Sun
标识
DOI:10.1021/acs.inorgchem.5c06062
摘要
Iron-nitrogen-carbon materials are promising nonprecious-metal catalysts for oxygen reduction reaction, yet their active-site density is inherently limited by conventional high-temperature synthesis. Herein, we introduce a precursor-mediated synthesis strategy that overcomes this bottleneck by using ferrous oxalate as a highly dispersed iron source. Controlled low-temperature decomposition generates ultrafine FeOx nanoparticles, which are subsequently converted into atomically dispersed Fe-N4 sites during pyrolysis. The concomitant release of CO2 concurrently etches the carbon matrix, creating additional defects and microporosity. This approach achieves a high site density of 1.18 × 1020 sites g-1 (3.4 ± 0.6 atoms nm-2). The resulting catalyst exhibits outstanding ORR performance in acidic medium, with a half-wave potential of 0.825 V vs RHE, and achieves a peak power density of 1.43 W cm-2 in a practical H2-O2 fuel cell. Operando X-ray absorption spectroscopy further reveals the reversible structural dynamics of the Fe-N4 sites, which switch between tetra- and penta-coordinated configurations during the reaction, directly evidencing that such coordination flexibility optimizes intermediate adsorption/desorption and enhances catalytic activity. This work provides a practical route to break the site-density ceiling in Fe-N-C catalysts and delivers insights into coordination-environment evolution of single-atom centers under working conditions.
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