Electrochemical potential gap in radicals: Why organic radicals do not disproportionate in solution?

The physical origin of the electrochemical potential gap (ΔE0 = E0Ox − E0Red) in radicals is discussed. It was shown that the EC gap in radicals is well approximated by two-electron Coulomb repulsion between the unpaired electron of the parent radical and an additional electron appeared in the SOMO...

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Bibliographic Details
Published inElectrochimica acta Vol. 460; p. 142632
Main Authors Levitskiy, Oleg A., Sentyurin, Vyacheslav V., Bogdanov, Alexey V., Magdesieva, Tatiana V.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 20.08.2023
Subjects
Coulomb integral
Electrochemical potential gap
Electron transfer
Radicals
Spin density
Electron transfer
Spin density
Coulomb integral
Electrochemical potential gap
Radicals
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Summary:The physical origin of the electrochemical potential gap (ΔE0 = E0Ox − E0Red) in radicals is discussed. It was shown that the EC gap in radicals is well approximated by two-electron Coulomb repulsion between the unpaired electron of the parent radical and an additional electron appeared in the SOMO after reduction. This repulsion prevents the disproportionation of radicals and makes possible their existence in solution. Assuming the density distribution of both electrons to be similar to that in the parent radical, the self-Coulomb integral of the spin density (K) provides a quantitative measure for the spin delocalization and for the estimation of a vertical electron transfer energy gap. Linear correlation between the experimentally measured electrochemical gaps and the integral K was found. Validity of the theoretical model was supported by experimental and computational data for a representative set of persistent radicals (46 examples). [Display omitted]
ISSN:0013-4686
DOI:10.1016/j.electacta.2023.142632