双金属片
材料科学
合理设计
催化作用
电子转移
密度泛函理论
选择性
异质结
极化(电化学)
催化循环
化学物理
降级(电信)
调制(音乐)
动力学
纳米技术
化学工程
铁磁性
电子
相(物质)
光化学
电子结构
自旋(空气动力学)
自旋极化
激进的
硫黄
光催化
设计要素和原则
析氧
作者
Yanhua Peng,Yaxin Cheng,Jingdan Shi,Qiming Zhang,Fanxu Meng,Xiaojia Huang,Xin Yu,Ren Wei,Ting Wang
标识
DOI:10.1002/adfm.202522458
摘要
Abstract Rational spin‐states modulation in bimetallic catalysts presents a promising strategy to enhance both the activity and selectivity of advanced oxidation processes. However, the underlying spin‐electronic mechanisms, particularly in structurally complex, multiphase systems, remain insufficiently understood. In this study, a sulfur‐assisted phase engineering strategy is employed to tune the structure of cobalt‐iron catalysts between spinels (CoFe 2 O 4 and CoFe 2 S 4 ) and heterojunctions (CoS@Fe 3 S 4 and Co 3 S 4 @Fe 3 S 4 ). Integrated experimental and density functional theory (DFT) analysis reveal that sulfur incorporation triggers asymmetric spin‐state modulation, characterized by enhanced electron localization in low‐spin‐state Co sites and significant spin polarization on S atoms. Such electronic configuration opens a directional Co─S─Fe electron spin channel in bimetallic sulfides, which promotes interfacial electron transfer and initiates the proton‐coupled electron transfer (PCET) process, thereby enabling efficient activation of peroxymonosulfate (PMS) and selective generation of nonradical 1 O 2 species. The resulting CoS@Fe 3 S 4 catalytic system demonstrates ≈14‐fold increase in reaction kinetics compared to CoFe 2 O 4 spinels, alongside high environmental applicability (Life Cycle Assessment) and minimal ecotoxicity of degradation intermediates. These findings highlight the critical role of asymmetric spin‐state modulation in governing reactive oxygen species (ROS) pathways, providing a rational design strategy for tunable advanced oxidation processes.
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