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Abstract
It is important but challenging to elucidate the electrochemical reaction mechanisms of organic compounds using electroanalytical methods. In this work, we exploited the advantages of classic thin-layer electrochemistry to develop a thin-layer electroanalysis microchip (TEAM). The TEAM provided better resolved voltammetric peaks than measurements under semi-infinite diffusion conditions. Importantly, because the analyte solution was mechanically isolated using a polyelectrolyte gel, rapid small-volume electrolysis allowed the accurate determination of the number of electrons transferred, n. The performance of the TEAM was validated using both voltammetry and coulometry of standard redox couples. Moreover, a spectroelectrochemical analysis of FM 1-43,
an organic dye widely used in neuroscience, was successfully performed. Harnessing the analytical power of the TEAM, the electrochemical oxidation mechanisms of pivanilides and alkyltrifluoroborate salts were studied. Thus,
the TEAM has the potential to provide invaluable mechanistic information and promote the rational design of electrosynthetic strategies.
Supplementary materials
Title
Supplementary Information
Description
Experimental details; additional simulation data
and explanation; cross-sectional diagram of TEAM; synthetic scheme of pLA-TFPB, peak-to-peak separation of ferrocyanide CVs; n–t plot without polyelectrolyte gel; CVs of Fc, FM1-43, and 4-MePhNHPiv with semi-infinite
diffusion; summary of oxidation potential and n.
Actions
Title
Video S1
Description
Video of simulated concentration profile change in thin-layer cell.
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