催化作用
电子顺磁共振
化学
钴
过渡金属
未成对电子
密度泛函理论
化学物理
光化学
无机化学
激进的
计算化学
核磁共振
有机化学
物理
作者
Rumeng Zhang,Hao Zhou,Tao Shao,Qiyu Lian,Mengliang Hu,Ji Mei,Shulin Zuo,Jiahao Huang,Zhuoyun Tang,Dehua Xia
出处
期刊:Angewandte Chemie
[Wiley]
日期:2025-05-14
卷期号:64 (29): e202507109-e202507109
被引量:19
标识
DOI:10.1002/anie.202507109
摘要
Catalytic ozonation technology is crucial for environmental remediation due to its exceptional efficiency and capability for complete mineralization of organic pollutants. However, hindered by spin-forbidden transitions, effective catalytic ozonation remains contingent upon the electronic properties and interfacial interactions of the catalyst. Recent studies identify interfacial atomic metal-oxygen species (*O) as a key descriptor in catalytic ozonation, determining the derivation of reactive species and subsEquationuent reactivity. Herein, we modulated the high-spin localized Co active sites in HE-Co3O4 via a high-entropy strategy, which selectively stabilizes *O surface species, thereby enhancing catalytic ozonation efficiency. HE-Co3O4 exhibits a five-fold higher degradation rate than Co3O4 for 50 ppm CH3SH elimination (63-fold the mass activity compared to commercial MnO2) while maintaining exceptional stability over 24 h at 298 K. Electron paramagnetic resonance (EPR) and magnetization hysteresis (M-H) measurements confirm the transition of Co3+ to high-spin states in HE-Co3O4. Density functional theory (DFT) calculations reveal that unpaired electrons enhance the hybridization of Co 3d with O 2p orbitals, thereby establishing a *O-mediated interfacial pathway. This mechanism is directly observed through in situ Raman spectroscopy. These findings provide insights into the targeted modulation of catalyst electronic structures for ozone-catalyzed environmental remediation.
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