Photographic measurements of propagation speeds of the conducting zone in polyaniline films during electrochemical switching

Aoki, Koichi; Aramoto, T.; Hoshino, Yoshimasa

doi:10.1016/0022-0728(92)80293-d

Cited by 67 publications

(35 citation statements)

References 14 publications

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“…These elements include a resistor to describe transport in the electrolyte, a capacitor (usually modeled with a constant phase element) in parallel with a charge transfer resistor to model the process of ion injection into the film, and a diffusion element (modeled with a Warburg or a constant phase element) to capture ion diffusion inside the polymer. 20 An alternative approach to study ion injection and transport in conjugated polymers is the socalled "moving front" experiment, [21][22][23] which relies on the fact that the optical absorption spectra of these materials change upon doping (electrochromism). In this experiment, changes in the optical density are spatially and temporally resolved in order to infer the injection and transport of ions inside a polymer film.…”

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confidence: 99%

A physical interpretation of impedance at conducting polymer/electrolyte junctions

et al. 2014

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We monitor the process of dedoping in a planar junction between an electrolyte and a conducting polymer using electrochemical impedance spectroscopy performed during moving front measurements. The impedance spectra are consistent with an equivalent circuit of a time varying resistor in parallel with a capacitor. We show that the resistor corresponds to ion transport in the dedoped region of the film, and can be quantitatively described using ion density and drift mobility obtained from the moving front measurements. The capacitor, on the other hand, does not depend on time and is associated with charge separation at the moving front. This work offers a physical description of the impedance of conducting polymer/electrolyte interfaces based on materials parameters.

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confidence: 99%

A physical interpretation of impedance at conducting polymer/electrolyte junctions

et al. 2014

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“…A physical meaning of this variation is that the term, vðÀxÞ shows a larger variation with the current than vðxÞ because of the stronger electric field effect in the more resistive domain. This deviation has been found in the plots for polyaniline [4,5] and polypyrrole films [6,8], as shown in Fig. 4.…”

Section: Theorymentioning

confidence: 81%

“…In order to evaluate the transfer coefficient from the growth experiment of the conducting zone, we have measured distances of the conducting front from the electrode at various electrolysis times after a given electrode potential is applied to the electrode [4][5][6]16]. The current density should be proportional to the velocity of the moving front if the growing domain is rectangular.…”

Section: Theorymentioning

confidence: 99%

“…When a conducting polymer in the insulating state is switched electrochemically into the conducting state in sufficient concentrations of dopant ion, the conducting zone grows clearly from the electrode at the expense of the insulating domain [4][5][6][7][8][9][10][11]. The growth occurs in the direction normal to the electrode.…”

Section: Introductionmentioning

confidence: 97%

“…The rate is predicted to be expressed by the Tafel or the Butler-Volmer equation. When the Tafel type equation was applied to the relation between the propagation rate and the electrode potential, the transfer coefficient evaluated from the plot of the logarithms of propagation rate against the applied potential was close to 0.1 for polypyrrole [8,21] as well as for polyaniline [4,5]. This value is extraordinarily small in comparison with conventional values close to 0.5 [22].…”

Section: Introductionmentioning

confidence: 99%

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An interpretation of small values of the transfer coefficient at conducting polymers

Aoki¹

2004

Journal of Electroanalytical Chemistry

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The electrochemical oxidation of electronically conducting polymers has shown values of the anodic transfer coefficient close to zero at the Tafel equation, rather than 0.5. This experimental result is interpreted in this report as a difference between the ionic conductance in the reactant in the neutral state and the electric conductance in the product in the polaron state. Since the electric conductance generates a lower electric field for the charged activated complex than the ionic conductance in the reaction coordinate, it compels the activated complex to move less toward the reactant than toward the product. The asymmetry of the activation potential hill makes the anodic transfer coefficient small. This concept is demonstrated by use of the Langevin equation for the activated complex at the activation energy hill. The transfer coefficient is expressed in terms of the thermal fluctuation of the conductance, and the current density. The Tafel plot shows a convex deviation from a straight line, and depends on applied potential, as is consistent with experimental results.

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Transport and Kinetics in Electroactive Polymers

Lyons¹

1996

Advances in Chemical Physics

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Photographic measurements of propagation speeds of the conducting zone in polyaniline films during electrochemical switching

Cited by 67 publications

References 14 publications

A physical interpretation of impedance at conducting polymer/electrolyte junctions

A physical interpretation of impedance at conducting polymer/electrolyte junctions

An interpretation of small values of the transfer coefficient at conducting polymers

Transport and Kinetics in Electroactive Polymers

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