催化作用
吸附
质子交换膜燃料电池
杂原子
氧气
化学工程
化学
活动站点
动力学
无机化学
工作(物理)
膜
化学气相沉积
质子
材料科学
密度泛函理论
金属
兴奋剂
化学动力学
Boosting(机器学习)
反应中间体
反应机理
化学反应
多相催化
功率密度
燃料电池
作者
Lin Lin,Xiu-Xuan Hou,Zhe-Chen Fan,Yi-Xuan Yin,Wei-Yi Zhao,Kai Wei,Yu-Die Zhou,Li-Na Hou,Ying Wang,Hao Wan,Junjie Ge
标识
DOI:10.61558/2993-074x.3592
摘要
Fe-N-C catalysts have long suffered from kinetically sluggish oxygen reduction reaction (ORR) due to excessive adsorption strength toward oxygen intermediates and low site utilization. Heteroatom doping effectively accelerates ORR reaction kinetics through electronic structure modulation of metal sites for optimal intermediate adsorption, while chemical vapor deposition (CVD) enhances the turnover frequency (TOF) of active sites. Herein, we developed an FeSNC catalyst featuring abundant FeS1N4 sites via a dual-precursor CVD strategy. Experimental and theoretical analyses revealed that S incorporation disrupts the symmetric coordination of active sites, which optimizes OH* adsorption energies from 0.212 eV to 1.194 eV. Moreover, the TOF increased from 1.98 e–1·site–1·s–1 to 6.32 e–1·site–1·s–1, significantly enhancing the intrinsic activity of the catalyst. More notably, the hydrophilic character of S-containing species substantially improved hydrophilicity in the S-doped catalyst, thereby promoting mass transport of oxygen and proton delivery. As a result, the FeSNC catalyst exhibited an extremely high half-wave potential of 0.863 V in 0.1 mol·L–1 HClO4 and achieved a peak power density of 1.2 W·cm–2 in H2-O2 PEMFCs. This work highlights the critical role of coordination engineering.
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