Flow-through electrochemical removal of benzotriazole by electroactive ceramic membrane

•A novel electrochemical system with titanium suboxide electroactive ceramic membrane is developed.•BTA undergoes pH-dependent indirect electrooxidation.•Acid-base boundary layer on the electrode surface is destroyed in flow-through electrochemical system.•Mechanisms and possible BTA degradation pat...

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Bibliographic Details
Published in:Water research (Oxford) 2022-06, Vol.218, p.118454-118454, Article 118454
Main Authors: Wang, Shengli, Pei, Shuzhao, Zhang, Jinna, Huang, Junqiang, You, Shijie
Format: Article
Language:English
Subjects:
Animals
benzotriazole
Ceramics
electroactive ceramic membrane
Electrodes
flow pattern
Oxidation-Reduction
Rats
Triazoles - chemistry
Water Pollutants, Chemical - chemistry
Water Purification
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Summary:•A novel electrochemical system with titanium suboxide electroactive ceramic membrane is developed.•BTA undergoes pH-dependent indirect electrooxidation.•Acid-base boundary layer on the electrode surface is destroyed in flow-through electrochemical system.•Mechanisms and possible BTA degradation pathways are proposed.•Toxicity of BTA is reduced during electrochmical oxidation. Benzotriazole (BTA) is a widely used anticorrosive additive that is of endurance, bioaccumulation and toxicity, and BTA industrial wastewater treatment remains a challenge. This study reports efficient electrochemical removal of BTA by titanium oxide (TiSO) electroactive ceramic membrane (ECM), indicated by 98.1% removal at current density of 20 mA∙cm−2 and permeate flux of 692 LHM under cathode-to-anode flow pattern (1 h). Electrochemical analysis demonstrated the pH-dependent formation of anti-corrosive BTA film on the TiSO anode, which was responsible for improved BTA removal for cathode-to-anode (CA) flow pattern compared with that for anode-to-cathode (AC). The modelling results showed the CA flow pattern to be more favourable for BTA oxidation mediated by electro-generated •OH by preventing the formation of deactivation film via creating an alkaline boundary layer at the anode/electrolyte interface. Intermediates and essential active sites were identified by using experimental analysis and theoretical density functional theory (DFT) calculations, thereby the most likely degradation pathways were underlined. Toxicity analysis revealed remarkable decrease in oral rat LD50 values and bioaccumulation factor during electrochemical degradation of BTA. This study provides a proof-in-concept demonstration of effective removal for anti-corrosive emerging pollutants by TiSO-ECM under flow-through pattern. [Display omitted]
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2022.118454