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Chemosphere


Title:Semi-solid electrolyte with layered heterometallic low-valent electron-mediator enabling indirect destruction of gaseous toluene
Author(s):Choi Y; Govindan M; Kim D;
Address:"Department of Environmental Engineering, Seoul National University of Science and Technology, Seoul, 01811, Republic of Korea. Department of Environmental Engineering, Seoul National University of Science and Technology, Seoul, 01811, Republic of Korea. Electronic address: kimd@seoultech.ac.kr"
Journal Title:Chemosphere
Year:2023
Volume:20221216
Issue:
Page Number:137590 -
DOI: 10.1016/j.chemosphere.2022.137590
ISSN/ISBN:1879-1298 (Electronic) 0045-6535 (Linking)
Abstract:"The electrochemical degradation of air pollutants, particularly volatile organic compounds (VOCs), at their gaseous state is a promising method. However, it remains at an infant stage due to sluggish solid-gas electron transfers at room temperature. We established a triphase reaction condition using a semi-solid electrolyte layer between the electrode and membrane to enhance the electron transfer at room temperature. A polyvinyl alcohol (PVA) gel layer was inserted between a bimetallic layered CuNi(CN)(4) complex coated Cu foam electrode (TCNi-Cu) and Nafion 324 membrane for the degradation of gaseous toluene. The cyclic voltammetry of TCNi-Cu using a sodium hydroxide-coated copper mesh electrode at a triphase showed Cu(1+) and Ni(1+) stabilization at -0.7 and -0.9 V, respectively, which was similar to the liquid phase electron transfer behavior. The degradation capacity of gaseous toluene without using electrogenerated TCNi-Cu + PVA gel was 0.54 mg cm(2) min(-1), whereas that of TCNi-Cu + PVA gel layers was 1.17 mg cm(-2)min(-1), which revealed the mediation effect at a triphase condition. Toluene was converted into oxygen-containing products, such as butanol, propanol, and acetone (without reduction products), which revealed that indirect oxidation occurred at the cathode using an in-situ generated oxidant, such as OH radical. As an electron-mediator, Cu(1+) was used to form oxidants for the degradation of toluene at -0.7 V. The toluene removal rate reached 1.4 mumol h(-1), with an energy efficiency of 0.15 Wh L(-1). This study is the first attempt to describe a liquid-electrolyte-free cathodic half-cell in electrochemical application to VOCs degradation, highlighting the electron transfer at room temperature"
Keywords:Humans *Gases Toluene/chemistry Electrons *Air Pollutants/analysis Oxidation-Reduction Oxidants Cathodic half-cell Electron mediator Gaseous toluene removal Triphase reaction;
Notes:"MedlineChoi, Youngyu Govindan, Muthuraman Kim, Daekeun eng England 2022/12/20 Chemosphere. 2023 Feb; 313:137590. doi: 10.1016/j.chemosphere.2022.137590. Epub 2022 Dec 16"

 
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