Development and Use of a Real-time In-situ Monitoring Tool for Electrochemical Advanced Oxidation Processes

IF 6.1 Q1 CHEMISTRY, MULTIDISCIPLINARY

Chemistry methods : new approaches to solving problems in chemistry Pub Date : 2023-03-30 DOI:10.1002/cmtd.202300014

Chelsea M. Schroeder, Arturo León Sandoval, Kristiane K. Ohlhorst, Dr. Nicholas E. Leadbeater

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Abstract

An apparatus for real-time in-situ monitoring of electrochemical advanced oxidation processes using visible spectrophotometry has been developed. Central to the design is a 3D-printed sleeve that interfaces commercially available electrochemical and spectrophotometry units. Using the anodic oxidation of Acid Orange 7 as a test bed, the apparatus has been used for probing the impact of varying electrode composition, current density, electrolyte concentration, and stirring speed on the rate of decolorization. In addition, the unit was used to prove that decolorization can continue after electrolysis has been stopped, thereby showing the inherent value of real-time monitoring. Given that a significant challenge in the field of advanced oxidation processes is the inability to compare different reported systems, our approach, using commercially available equipment and a printable interface may open avenues for more standardized data collection.

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电化学高级氧化过程实时原位监测工具的开发和使用

研制了一种利用可见分光光度法实时监测电化学高级氧化过程的装置。该设计的核心是一个3d打印的套筒，它与市售的电化学和分光光度仪相连接。以酸性橙7的阳极氧化为实验平台，研究了不同电极组成、电流密度、电解质浓度和搅拌速度对脱色速率的影响。另外，用该装置证明了电解停止后，脱色仍可继续，显示了实时监测的内在价值。鉴于高级氧化过程领域的一个重大挑战是无法比较不同的报告系统，我们的方法，使用商用设备和可打印接口，可能为更标准化的数据收集开辟道路。

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来源期刊

Chemistry methods : new approaches to solving problems in chemistry

CiteScore

7.30

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0.00%

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