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Redox Hopping in Metal–Organic Frameworks through the Lens of the Scholz Model

Minliang Yan, Eric M. Johnson, Amanda J. Morris

2023The Journal of Physical Chemistry Letters12 citationsDOI

Abstract

Initially proposed by Lovric and Scholz to explain redox reactions in solid-phase voltammetry, the Scholz model’s applications have expanded to redox reactions in various materials. As an extension of the Cottrell equation, the Scholz model enabled the quantification of electron hopping and ion diffusion with coefficients, D e and D i, respectively. Research utilizing the Scholz model indicated that, in most cases, a huge bottleneck results from the ion diffusion which is slower than electron hopping by orders of magnitude. Therefore, electron and ion motion can be tuned and optimized to increase the charge transport and conductivity through systematic investigations guided by the Scholz model. The strategy may be extended to other solid-state materials in the future, e.g., battery anodes/cathodes. In this Perspective, the applications of the Scholz model in different materials will be discussed. Moreover, the limitations of the Scholz model will also be introduced, and viable solutions to those limitations discussed.

Topics & Concepts

DiffusionRedoxBattery (electricity)ElectronExtension (predicate logic)IonChemistryPhysicsStatistical physicsMaterials scienceThermodynamicsQuantum mechanicsComputer scienceInorganic chemistryPower (physics)Programming languageElectrochemical Analysis and ApplicationsConducting polymers and applicationsTransition Metal Oxide Nanomaterials
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