The Electrochemistry Group Medal Lecture. Electron self-exchange dynamics between redox sites in polymers

Surridge, Nigel A.; Jernigan, J. C.; Dalton, E. F.; Buck, Richard P.; Watanabe, Masayoshi; Zhang, H.; Pinkerton, M. J.; Wooster, T. T.; Longmire, M. L.; Facci, John S.; Murray, Royce W.

doi:10.1039/dc9898800001

Cited by 67 publications

(46 citation statements)

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“…The potential materials for solid-state electrochemical measurements are expected to contain three-dimensionally distributed, highly concentrated redox centers between which fast electron selfexchange (hopping) is feasible [13][14][15][16]. These redox centers are fixed and, although they may have short range mobility about an equilibrium position, they classically are macroscopically immobile.…”

Section: General Considerationsmentioning

confidence: 99%

“…In the latter case, the charge-compensating counterions originate from an infinite, external source, the liquid supporting electrolyte. For solid-state measurements in the absence of bulk liquid phase, the systems to be investigated are expected to contain not only the redox centers, which are highly concentrated and practically immobile [13][14][15], but also a sufficiently large 'ionic budget' [14] of mobile, structural counterions.…”

Section: Introductionmentioning

confidence: 99%

“…Potential applications of solid-state electrochemical measurements include such diverse areas as charge storage in batteries and redox supercapacitors [18][19][20], electrochromism [21,22], electrosynthesis [23], molecular electronics [11,24,25], characterization of mixed-valence ionically conducting materials [14][15][16], and the development of novel amperometric sensors for gases [26][27][28]. In the latter case, the measurement concept is based on electrocatalysis at the gas-solid interface.…”

Section: Introductionmentioning

confidence: 99%

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Solid-State Voltammetry — Analytical Prospects

Kulesza¹,

Cox

1998

Electroanalysis

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The present review discusses some current issues related to the principles and analytical aspects of electrochemical studies (typically done at room temperature) of solid, rigid or semirigid (nonfluid) systems in the absence of a liquid solution phase. Representative examples include redox and conducting organic polymers, melts and solid solutions of redox centers in solid ionic conductors, mixed-valence polynuclear inorganic materials, transition metal salts, oxides, and zeolites. The emphasis is on the elements of dynamics for the efficient delivery of charge and on reactivity of the 'redox conducting' materials. The effective (apparent) diffusional mechanism is critical to the success of most analytical measurements in solidstate. Also described are typical electrochemical cells and experimental tactics to overcome the relatively slow dynamics of transport in solid (nonfluid) systems. Application of microdimensional electrodes leads to an improvement in the quality of solid-state electrochemical data and provides new diagnostic and analytical possibilities. Results of mechanistic studies, which are relevant to the development of novel analytical methods, together with trends towards possible future applications also are discussed.

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Section: General Considerationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Solid-State Voltammetry — Analytical Prospects

Kulesza¹,

Cox

1998

Electroanalysis

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“…Among the important requirements for a material to reveal electroactivity in solid, rigid, or semirigid state, in the absence of external liquid electrolyte, essential is the existence of mixed-valence redox centers and mobile charge-compensating ions [16][17][18][19][20]. Moreover, to minimize such parameters as ohmic resistance and migration effect, the concentration of charged species, like mobile ions and electrons, should be fairly large in the system.…”

Section: Introductionmentioning

confidence: 99%

Solid-state electrochemical behavior of Keggin-type borotungstic acid single crystal

Adamczyk

Miecznikowski

2013

J Solid State Electrochem

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We demonstrate the electrochemical characteristics of the, poorly described in the literature, mixed-valence proton conducting solid borotungstic acid single crystal, H 5 BW 12 O 40 xH 2 O, in the absence of liquid electrolyte phase. We performed electrochemical measurements in an all-solid cell with a gold fiber ultramicrodisk (diameter 10, 25, and 40 μm) working electrode, a silver semi-reference disk electrode, and a glassy carbon ring counter electrode. Diagnostic experiments at different scan rates aimed at probing the model of mass transport and potential kinetic limitations. Such bulk parameters as the effective diffusion coefficient of charge propagation and the concentration of mixed-valence redox centers were determined by two methods. The first method is based on the analysis of both Cottrellian and steady-state currents (the mixed-regimes method), and the second method provides the true diffusion coefficient (transport coefficient free of the migration influence) for both the substrate and the product of the electrode reaction. Together, these methods constitute a double potential step chronoamperometry experiment. The data obtained with these electrochemical experiments (effective diffusion coefficients, concentration of mixed-valence redox centers, etc.) can support the results obtained with other techniques (XRD, FTIR, and TGA).

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“…Because charge displacement in supercapacitors could be largely interfacial and no diffusional limitations there exist, they can become high power devices. To fabricate high-energy density rechargeable battery-type materials, one has to refer to fundamental concepts of fast redox transitions within thin solid films of redoxconducting materials [6][7][8][9]. Applicable systems include protonically/electronically conducting mixed valence inorganic materials (e.g., polyoxometalates of molybdenum or tungsten [10][11][12][13]) and certain organic conjugated conducting polymers (e.g., pristine or derivatized poly (3,4-ethylenedioxythiophene), PEDOT [14,15]).…”

Section: Introductionmentioning

confidence: 99%

Development of copper-stabilized conducting-polymer/polyoxometalate hybrid materials for effective electrochemical charging

Adamczyk

2016

J Solid State Electrochem

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A hybrid organic-inorganic material composed of poly (3,4-ethylenedioxythiophene), PEDOT, derivatized with 4-(pyrrol-e1-yl) benzoic acid, PyBA, and Keggin-type copper (II)-salt of H 3 PMo 12 O 40 has been proposed here. Such features as good electronic conductivity of PEDOT, hydrophilic and coordination capabilities of PyBA, the ability of copper ( I I ) i o n s t o l i n k P y B A c ar b ox y l i c g r o u p s , a n d phosphomolybdate anionic sites, as well as high protonic and mixed-valence conductivities of H 3 PMo 12 O 40 have been explored here to produce a stable composite material charcterized by reasonable charge propagation dynamics. Characterization and formation of the hybrid ca. 0.6 μm thick PEDOT/PyBA-Cu x H y PMo 12 O 40 films have been asessed by FTIR, XRD, AFM, SEM, as well as using electrochemical methods. Among important feautures of the proposed hybrid system is the ability to undergo reversible charging/ discharhging (both under voltammetric and galvanostatic conditions) in a manner analogous to what is observed in battery--type cells. Typical parameters, such as specific capacity, energy, and power densities, are provided and discussed.

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The Electrochemistry Group Medal Lecture. Electron self-exchange dynamics between redox sites in polymers

Cited by 67 publications

References 1 publication

Solid-State Voltammetry — Analytical Prospects

Solid-State Voltammetry — Analytical Prospects

Solid-state electrochemical behavior of Keggin-type borotungstic acid single crystal

Development of copper-stabilized conducting-polymer/polyoxometalate hybrid materials for effective electrochemical charging

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