电合成
工艺工程
连续反应器
流动化学
电化学
连续流动
流量(数学)
化学反应工程
生化工程
计算机科学
优势和劣势
纳米技术
化学反应器
领域(数学)
光催化
微型反应器
反应条件
间歇式反应器
化学过程
催化作用
化学反应
材料科学
绿色化学
化学
反应堆设计
封面(代数)
电化学电池
连续搅拌釜式反应器
环境科学
有机合成
电子
化学工程
均相催化
作者
Tomas Hardwick,Nisar Ahmed
标识
DOI:10.1021/acs.iecr.5c03301
摘要
In the past few years, the immense synthetic capability of electrophotocatalysis, the hybrid methodology of electrochemistry and photochemistry, has been realized owing to advancements in each field over the past couple of decades. This has been driven by the desire to obtain more efficient and sustainable synthetic practices, which is made possible by using two of the most abundant and well-known substances as traceless reagents, namely electrons and photons. It has been realized that while electrosynthesis and photoredox catalysis are imperfect, their respective strengths can nearly perfectly compensate for the weaknesses of the other. Moreover, continuous flow chemistry has also emerged as an improved strategy in which to conduct chemical transformations, particularly in terms of reaction screening and scale-up. In this review, we cover advancements in electrophotocatalysis but do so while predominantly focusing on those conducted through continuous flow reactors. This is then taken a step further by taking an engineering approach to reactor design. We discuss two configurations of reactor setups, one in which multiple photo- and electrochemical reactors are connected in series, termed “Sequential Electrophotochemical Flow”, and the other in which the design and materials of a single reactor are such that electrochemical and photochemical reactions occur simultaneously, termed “Electrophotochemical Flow with Transparent Electrodes”. The examples associated with each are taken from academic works for the purposes of proof of concept and reaction scope; where available, they are compared to a batch counterpart.
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