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Electric field enhanced heterogeneous Fenton reaction: simultaneous pollutant degradation and catalyst reactivation
Journal of Chemical Technology and Biotechnology ( IF 3.4 ) Pub Date : 2022-07-19 , DOI: 10.1002/jctb.7194 Zijie Zhou 1 , Xu Yin 1 , Wei Li 1 , Run Liu 1 , Kajia Wei 1 , Xiaodong Liu 1 , Xiuyun Sun 1 , Weiqing Han 1
Journal of Chemical Technology and Biotechnology ( IF 3.4 ) Pub Date : 2022-07-19 , DOI: 10.1002/jctb.7194 Zijie Zhou 1 , Xu Yin 1 , Wei Li 1 , Run Liu 1 , Kajia Wei 1 , Xiaodong Liu 1 , Xiuyun Sun 1 , Weiqing Han 1
Affiliation
Traditional Fe-based heterogeneous Fenton catalysts have the problem of a low generation rate of Fe(II) from Fe(III), and this leads to poor reaction efficiency and catalyst deactivation. In this work, Fe3O4@N-MWCNT catalyst with both strong magnetism and high electrical conductivity was synthesized. In addition, a novel unibody degradation-reactivation reactor was designed for simultaneous pollutant degradation and catalyst reactivation.
中文翻译:
电场增强非均相芬顿反应:同时降解污染物和催化剂再活化
传统的 Fe 基非均相 Fenton 催化剂存在 Fe(III) 生成 Fe(II) 的速率低的问题,这导致反应效率差和催化剂失活。本工作合成了兼具强磁性和高导电性的Fe 3 O 4 @N-MWCNT催化剂。此外,还设计了一种新型单体降解-再活化反应器,用于同时降解污染物和催化剂再活化。
更新日期:2022-07-19
中文翻译:
电场增强非均相芬顿反应:同时降解污染物和催化剂再活化
传统的 Fe 基非均相 Fenton 催化剂存在 Fe(III) 生成 Fe(II) 的速率低的问题,这导致反应效率差和催化剂失活。本工作合成了兼具强磁性和高导电性的Fe 3 O 4 @N-MWCNT催化剂。此外,还设计了一种新型单体降解-再活化反应器,用于同时降解污染物和催化剂再活化。
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