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Rapid Electrochemical Assessment of Excited-State Quenching Dynamics

Tobia Casadei, Alberto Piccoli, Davide Zeppilli, Laura Orian, Abdirisak Ahmed Isse, Marco Fantin

2025ACS Catalysis7 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Recent advancements in electro-photoredox catalysis (e-PRC) and consecutive photoinduced electron transfer (conPET) have pushed the energy limits of conventional photocatalysis. Both methods produce open-shell intermediate catalysts that, upon light absorption, become highly reducing or oxidizing, enabling challenging reactions. Despite their widespread use, the mechanisms of e-PRC and conPET reactions remain debated, in part due to a lack of quantitative data in most studies─particularly single-electron transfer rate constants ( k SET ) between excited-state catalysts and substrates. We present a straightforward electrochemical method for determining k SET using cyclic voltammetry (CV) under light irradiation, paired with electrochemical simulation. Using inexpensive LEDs and standard potentiostats, we investigated the reactivity of excited-state anions of a perylene diimide dye (PDI), the seminal catalyst of conPET reactions. CV was used to study the photochemical reactivity of both reduced species of PDI, *PDI •– and *PDI 2–, in the reductive cleavage of carbon–halogen bonds in alkyl and aryl halides. The extreme reactivity of these excited-state anions is confirmed, with quenching rate constants of 10 7 and 10 10 M –1 s –1 for *PDI •– and *PDI 2–, respectively, consistent with theoretical and experimental data. The voltammetric approach presented here provides a rapid and reliable tool for studying the excited-state reactivity of labile intermediates utilized in e-PRC and conPET systems, including both radical anions and dianions.

Topics & Concepts

Reactivity (psychology)DiimidePhotochemistryCatalysisChemistryElectrochemistryElectron transferPeryleneQuenching (fluorescence)Reaction rate constantCyclic voltammetryPhotoinduced electron transferArylAlkylCatalytic cycleReaction mechanismInorganic chemistryReaction rateCombinatorial chemistryReaction intermediatePhotoredox catalysisRedoxFluorescenceElectrochemical Analysis and ApplicationsCorrosion Behavior and InhibitionElectrocatalysts for Energy Conversion
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