纳米反应器
催化作用
化学
钴
普鲁士蓝
浸出(土壤学)
化学工程
光化学
无机化学
有机化学
物理化学
电极
电化学
土壤水分
土壤科学
工程类
环境科学
作者
Tingting Zhao,Yang Yang,Xianhe Deng,Shouchun Ma,Maoquan Wu,Yanqiu Zhang,Yina Guan,Yufeng Zhu,Tongjie Yao,Qing‐Feng Yang,Jie Wu
标识
DOI:10.1016/j.jcis.2022.06.065
摘要
Peroxymonosulfate (PMS)-based Fenton-like reaction is an effective technique for the pollutant degradation, and the Co-based metal organic frameworks displayed the excellent activity for the PMS activation. Nevertheless, how to further improve the catalytic activity, suppress the leaching of toxic cobalt ions, and realize the rapid separation were still challenges for practical application. In this work, a novel solution was proposed: encapsulating Fe3O4 and Prussian blue analogue (PBA) into the polypyrrole (PPy) shell and constructing a "double-yolk egg-like" Fe3O4/PBA@PPy as a nanoreactor. In Fe3O4/PBA@PPy-10, the catalytic performance was remarkably enhanced with the help of confinement effect, and the degradation rate (0.38 L·min·mol-1) was 5.1 times than that of reference Fe3O4/PBA-10 (0.074 L·min·mol-1). In addition, the concentration of leached cobalt ions was reduced to only 0.174 mg/L by the protective function from the PPy shell. Moreover, the nanoreactor could be magnetically separated from the reaction solution due to the encapsulation of Fe3O4 nanospheres, and 84.5% of activity still preserved after the 4th cycle. The main active species involved in Fe3O4/PBA@PPy-10 system was 1O2, while that in reference Fe3O4/PBA-10 system was OH. Electron spin resonance analysis and radical trapping experiment revealed that the different catalytic mechanisms were attributed to the confinement effect inside the hollow cavity. This work not only presents a feasible way to prepare rarely-reported double-yolk egg-like nanoreactor, but also provides a new insight to solve the bottlenecks in Fenton-like reaction.
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