New perspective on ECE mechanism of monohydroxycinnamic acid oxidation with carbon nanotube electrode

New perspective on ECE mechanism of monohydroxycinnamic acid oxidation with carbon nanotube electrode

•ECE mechanism of monohydroxycinnamic acid oxidation is presented.•A carbon nanotube-carboxymethylcellulose electrode is used.•Proposed mechanism is confirmed by simulations using DigiElch software.•Monohydroxycinnamic acids are converted into dihydroxycinnamic acids. In this study, the electrochemi...

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Bibliographic Details
Published in:Electrochimica acta Vol. 359; p. 136964
Main Authors: Wada, Ryotaro, Takahashi, Shota, Muguruma, Hitoshi
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-11-2020
Elsevier BV
Subjects:
Acids
Anodizing
Carbon nanotube
Carbon nanotubes
Catechol
Cyclic voltammetry
ECE mechanism
Electrodes
High performance liquid chromatography
Hydrolysis
Hydroxycinnamic acid
Hydroxyl groups
Oxidation
Quinones
Voltammetry
Carbon nanotube
Cyclic voltammetry
Hydroxycinnamic acid
ECE mechanism
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Summary:•ECE mechanism of monohydroxycinnamic acid oxidation is presented.•A carbon nanotube-carboxymethylcellulose electrode is used.•Proposed mechanism is confirmed by simulations using DigiElch software.•Monohydroxycinnamic acids are converted into dihydroxycinnamic acids. In this study, the electrochemical-chemical-electrochemical (ECE) mechanism of monohydroxycinnamic (ferulic, sinapic, and p-coumaric) acid oxidation is presented from a new perspective. Successful mechanistic interpretation employs a carbon nanotube (CNT)-carboxymethylcellulose (CMC) electrode, which exhibits distinctive ECE behavior in cyclic voltammetry (CV), unlike other electrodes. The proposed mechanism is confirmed by simulations using DigiElch software. Monohydroxycinnamic acids are oxidized by an EECE mechanism (ErErCiEr = A ⇄ B + e−; B ⇄ C + e−; C ⇄ D; D + 2e− ⇄ E). The first electrochemical step (ErEr) comprises two consecutive oxidations (A ⇄ B + e−; B ⇄ C + e−), which appear as separate anodic peaks. The reaction at the less positive potential involves oxidation of the hydroxyl group to a phenoxy radical (B), which exists in three mesomeric forms that are oxidized in the second reaction to cations (C) that undergo hydrolysis to their respective o-quinones (D). The hydrolysis reaction (C → D) exhibits a large rate constant and occurs rapidly on the voltammetric time scale. Thus, the overall ErErCi process appears to be chemically irreversible. Finally, the monohydroxycinnamic acids are converted into dihydroxycinnamic acids (caffeic or 5-hydroxyferulic acids), which condense into a reversible, two-electron catechol/o-quinone redox system (D + 2e− ⇄ E). Electrochemical quantitation is based on the proportionality of the peak currents to the monohydroxycinnamic acid concentration. The voltammetrically determined monohydroxycinnamic acid content in real food samples agrees with the high-performance liquid chromatography results. The CNT-CMC electrode extends fundamental studies of the ECE mechanism to systems that cannot be examined using conventional electrodes, thereby demonstrating its utility in electrochemical studies. [Display omitted]
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2020.136964