化学
羟基化
降级(电信)
催化作用
烷基
阿特拉津
核化学
光化学
杀虫剂
有机化学
生物
电信
计算机科学
农学
酶
作者
Peng Xu,Xiang Li,R. Wei,Peng Wang,Xiaojing Wang,Chunyan Yang,Tianyao Shen,Guangshan Zhang
标识
DOI:10.1016/j.cej.2022.135863
摘要
CuO-Fe2O3/MXene was fabricated using a rapid microwave hydrothermal method and used for the enhanced peroxymonosulfate (PMS) activation and atrazine (ATZ) degradation. The ATZ degradation rate could reach up to nearly 100% within 60 min at pH = 6.4, with low dosage for CuO-Fe2O3/5% MXene (0.1 g‧L-1) and PMS (0.37 mM). Experimental results and DFT calculations showed that coexisting matter had little influence on ATZ degradation at low concentrations, indicating the excellent anti-interference capability of the system. Circulation and interaction of ≡Fe(III)/≡Fe(II) and ≡Cu(II)/≡Cu(I) produced SO4•- and •OH, O* and SO5•- could participate in the formation of 1O2. Then, ATZ degradation pathways, including dealkylation, dichlorination-hydroxylation, alkyl hydroxylation, alkyl oxidation, olefination, and deamination-hydroxylation processes, were proposed based on DFT calculations and ESI-QTOF-MS/MS data. QSAR analysis illustrated that most intermediates were more environmentally friendly than ATZ. This study developed novel materials with superior catalytic performance for elimination of refractory organic pollutants in wastewater.
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