电合成
电解
电化学
微尺度化学
微电极
电极
纳米技术
图层(电子)
氧化还原
化学
电化学电池
化学工程
材料科学
无机化学
电解质
数学教育
数学
物理化学
工程类
作者
Buwanila T. Punchihewa,Vidit Minda,William G. Gutheil,Mohammad Rafiee
标识
DOI:10.1002/anie.202312048
摘要
Abstract Electrochemistry represents unique approaches for the promotion and mechanistic study of chemical reactions and has garnered increasing attention in different areas of chemistry. This expansion necessitates the enhancement of the traditional electrochemical cells that are intrinsically constrained by mass transport limitations. Herein, we present an approach for designing an electrochemical cell by limiting the reaction chamber to a thin layer of solution, comparable to the thickness of the diffusion layer. This thin layer electrode (TLE) provides a modular platform to bypass the constraints of traditional electrolysis cells and perform electrolysis reactions in the timescale of electroanalytical techniques. The utility of the TLE for electrosynthetic applications benchmarked using NHPI‐mediated electrochemical C−H functionalization. The application of microscale electrolysis for the study of drug metabolites was showcased by elucidating the oxidation pathways of the paracetamol drug. Moreover, hosting a microelectrode in the TLE, was shown to enable real‐time probing of the profiles of redox‐active components of these rapid electrosynthesis reactions.
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