通过二维电响应金属有机框架进行电驱动循环芬顿催化,实现水净化

Chao Yang, Shanshan Shang, Lin Lin, Pei Wang, Zhihong Ye, Yixuan Wang, Kaimin Shih, Lianpeng Sun, Xiao-yan Li
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引用次数: 0

摘要

电-芬顿工艺是一种消除水中新出现的有机污染物的前景广阔的技术。然而,由于缺乏具有持续芬顿反应所必需的循环催化功能的阴极材料,该技术的潜力受到了阻碍。在本研究中,我们开发了一种创新的催化阴极,由二维电响应二茂铁金属有机框架(ER-Fc-MOF)组成,可在无试剂双阴极电-芬顿过程中有效激活 H2O2。ER-Fc-MOF 阴极还能通过二茂铁夹层结构内的直接电子传递实现铁(II)位点的电驱动再生,从而实现 Fc+-Fe(III)/Fc-Fe(II) 物种在芬顿反应中的连续循环。电子顺磁共振和淬灭试验证实,ER-Fc-MOF 催化阴极可产生自由基(HO-)和非自由基(1O2)物种,在各种水基质中的宽 pH 值范围内高效降解有机污染物。这种用于电-芬顿过程的新型电反应循环催化剂为开发用于水净化和废水处理的绿色可持续氧化技术提供了一条前景广阔的途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Electro-driven cycling Fenton catalysis through two-dimensional electroresponsive metal–organic frameworks for water purification

Electro-driven cycling Fenton catalysis through two-dimensional electroresponsive metal–organic frameworks for water purification

Electro-driven cycling Fenton catalysis through two-dimensional electroresponsive metal–organic frameworks for water purification
The electro-Fenton process is a promising technology for eliminating emerging organic pollutants from water. However, its potential is hindered by the lack of cathode materials with the essential cycling catalytic functionality for sustained Fenton reactions. In this study, we developed an innovative catalytic cathode comprising a two-dimensional electroresponsive ferrocene metal–organic framework (ER-Fc-MOF) for effective H2O2 activation in a reagent-free dual-cathode electro-Fenton process. The ER-Fc-MOF cathode also enables the electro-driven regeneration of the Fe(II) sites through direct electron transfer within the ferrocene sandwich structure, achieving continuous cycling of the Fc+-Fe(III)/Fc-Fe(II) species for Fenton reactions. Electron paramagnetic resonance and quenching tests confirmed that the ER-Fc-MOF catalytic cathode generates both radical (HO·) and non-radical (1O2) species for highly efficient degradation of organic pollutants across a broad pH range in diverse water matrices. This novel electroresponsive cycling catalyst for the electro-Fenton process presents a promising route towards the development of green and sustainable oxidation technologies for water purification and wastewater treatment. Electro-Fenton treatment holds great promise as an advanced oxidation process for removing emerging organic pollutants, but achieving sustained Fenton reactions remains a challenge. An electroresponsive ferrocene metal–organic framework cathode now enables continuous cycling of the catalytic species for Fenton reactions and achieves efficient water purification.
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