Why approximating electrocatalytic activity by a single free‐energy change is insufficient

Progress in the area of electrocatalysis has been spurred by theoretical predictions, using the free energies of reaction intermediates within the electrocatalytic cycle as a measure to assess electrocatalytic activity. Most commonly, the framework of the thermodynamic overpotential, ηTD, is applied...

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Bibliographic Details
Published in:Electrochimica acta 2021-04, Vol.375, p.137975, Article 137975
Main Author: Exner, Kai S.
Format: Article
Language:English
Subjects:
Electrocatalysis
Electrochemical-step symmetry index
Gmax(η)
Oxygen evolution reaction
Thermodynamic overpotential
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Summary:Progress in the area of electrocatalysis has been spurred by theoretical predictions, using the free energies of reaction intermediates within the electrocatalytic cycle as a measure to assess electrocatalytic activity. Most commonly, the framework of the thermodynamic overpotential, ηTD, is applied to study activity trends of electrodes in a class of materials. The concept of ηTD, however, relies on the evaluation of a single free-energy change at the equilibrium potential of the reaction, which may explain that the notion of ηTD does not always capture activity trends correctly. To compensate this shortcoming, the electrochemical-step symmetry index (ESSI) was introduced, which accounts for all free-energy changes at the equilibrium potential among the mechanistic description. Yet, both ηTD and the ESSI do not consider overpotential and kinetic effects in the analysis, motivating the introduction of an overpotential-dependent activity descriptor for multiple-electron processes, Gmax(η). In this manuscript, these three descriptors to approximate electrocatalytic activity in a heuristic fashion are compared, elaborating that the assessment of activity by a single free-energy change is too simplistic. [Display omitted]
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2021.137975