Investigating the potential of pyrazine dioxide based-compounds as organic electrodes for batteries

Abstract

Understanding structure–property relationship in redox-active molecular species is of central importance in various fields, including many medicinal and chemical applications. The quest for performant organic electrodes in the context of energy storage calls for pioneering studies to develop new and possibly optimal materials. Beyond modifying the molecular design of the existing compounds through functionalization, expansion of the search enabling the advent of efficient new backbones can potentially lead to breakthroughs in this research area. The number of already identified families able to constitute negative organic electrodes is much lower than that of their positive counterparts, which calls for finding ways to bridge this gap. To expand the dataset of known predicted redox potentials and in view of reaching an educated guess about the abilities of some eventual new redox active electrodes, we examined the properties of pyrazine N,N′-dioxide (PZDO) and its fully methylated functionalized derivative (TeMePzDO). The aspects and mechanisms driving the various features characteristic of these compounds were unraveled through molecular and periodic DFT calculations combined with accurate electronic structure analysis. The predicted molecular redox/crystalline intercalation potentials lead to the classification of PZDO and TeMePzDO systems within the class of negative electrodes, with features that are significantly appealing compared to those of some existing systems with backbones suited for such kind of application.

Graphical abstract: Investigating the potential of pyrazine dioxide based-compounds as organic electrodes for batteries

Supplementary files

Article information

Article type
Paper
Submitted
18 Mme 2024
Accepted
06 Jan 2024
First published
15 Jan 2024

Dalton Trans., 2024, Advance Article

Investigating the potential of pyrazine dioxide based-compounds as organic electrodes for batteries

F. Lambert, A. L. Hetzel, Y. Danten, A. A. Franco, C. Gatti and C. Frayret, Dalton Trans., 2024, Advance Article , DOI: 10.1039/D4DT01144A

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