制氢
电解
分解
废水
乙醇胺
无机化学
氢
光催化
电解水
反应速率
废物管理
化学工程
化学
光化学
工程类
催化作用
有机化学
物理化学
电极
电解质
作者
Kyong‐Hwan Chung,Young‐Kwon Park,Sun-Jae Kim,Sang-Chai Kim,Sang‐Chul Jung
标识
DOI:10.1016/j.cej.2022.136725
摘要
• The wastewater contained ethanolamine was decomposed using a liquid plasma and an electrolysis. • A hybrid reaction system linked to the liquid plasma and electrolysis was developed for H 2 production. • Performance of COD and total nitrogen removal was also investigated to the wastewater. • The COD and total nitrogen were removed entirely in the consecutive reaction process. • The H 2 evolution rate was increased significantly by decomposition in the hybrid system. The development of a hybrid reaction system linking photochemical decomposition with liquid-phase plasma and photocatalyst and electrolysis in a consecutive reaction was attempted for efficient decomposition and hydrogen production from high-concentration ethanolamine-resistant wastewater. A consecutive process was developed in which ethanolamine wastewater was decomposed completely by an electrolysis process after first reducing the concentration of ethanolamine by a decomposition reaction through liquid phase plasma and photocatalyst in the first step. The chemical oxygen demand (COD) and total nitrogen removal performance of wastewater containing ethanolamine were also investigated using the consecutive process. The COD and nitrogen removal efficiency were higher in the photochemical reaction by liquid plasma and bismuth ferrite photocatalyst than by electrolysis in a single reaction. In the hybrid reaction linking the two reactions, the COD and total nitrogen were removed entirely. The hydrogen production rates obtained from the photochemical reaction by liquid plasma and bismuth ferrite photocatalyst were higher than the respective hydrogen production rates obtained by a single electrolysis reaction. The hydrogen production rate obtained from the hybrid reaction system was increased significantly. Hydrogen produced by a photocatalytic reaction using liquid plasma and hydrogen produced by electrolysis could increase the overall hydrogen production rate.
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