Effects of the dipolar double layer on elemental electrode processes at micro- and macro-interfaces

Determination of heterogeneous rate constants of redox reactions or charge transfer resistances always involves ambiguities due to their participation in double layer (DL) capacitances and solution resistances. The rate constants determined by steady-state voltammograms at ultra-microelectrodes are...

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Bibliographic Details
Published in:Faraday discussions 2018-10, Vol.21, p.219-234
Main Authors: Aoki, Koichi Jeremiah, Chen, Jingyuan
Format: Article
Language:English
Subjects:
Capacitance
Charge transfer
Dipoles
Electric double layer
Electrodes
Impedance
Microelectrodes
Rate constants
Redox reactions
Solvents
Time dependence
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Summary:Determination of heterogeneous rate constants of redox reactions or charge transfer resistances always involves ambiguities due to their participation in double layer (DL) capacitances and solution resistances. The rate constants determined by steady-state voltammograms at ultra-microelectrodes are inconsistent with time-dependent voltammograms, implying participation of the DL impedance. We examine controlling factors of DLs through the frequency-dependence of the capacitance on the basis of the definition of the current and the capacitance. The capacitance obeys the power law of the frequency. It is controlled by the orientation of a limited amount of solvent dipoles, independent of salts. Redox species, dipoles of which are oriented oppositely to the solvent dipoles, decrease the DL capacitance and make the value negative at high concentrations of the species. The decrease in the capacitance increases the real impedance, as predicted from the phase angle, yielding an extra resistance. This may be a ghost charge transfer resistance. However, there are actually a number of well-defined charge transfer resistances, which are observed as transferring rates through films on electrodes. The present work reveals the role of nano-interfaces on domain size and the thickness in the context of the relationship between double layer impedances and redox reactions.
ISSN:1359-6640
1364-5498
DOI:10.1039/c7fd00212b