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Reconciling Imbalanced and Nonadiabatic Reactivity in Transition Metal–Oxo-Mediated Concerted Proton Electron Transfer (CPET)

Joseph E. Schneider, John S. Anderson

2023The Journal of Physical Chemistry Letters10 citationsDOIOpen Access PDF

Abstract

Recently, there have been several experimental demonstrations of how the rates of concerted proton electron transfer (CPET) are affected by stepwise thermodynamic parameters of only proton (Δ G ° PT ) or electron (Δ G ° ET ) transfer. Semiclassical structure–activity relationships have been invoked to rationalize these linear free energy relationships, but it is not clear how they would manifest in a nonadiabatic reaction. Using density functional theory calculations, we demonstrate how a decrease in Δ G ° PT can lead to transition state imbalance in a nonadiabatic framework. We then use these calculations to anchor a theoretical model that reproduces experimental trends with Δ G ° PT and Δ G ° ET . Our results reconcile predictions from semiclassical transition state theory with models that treat proton transfer quantum mechanically in CPET reactivity, make new predictions about the importance of basicity for uphill CPET reactions, and suggest similar treatments may be possible for other nonadiabatic reactions.

Topics & Concepts

Semiclassical physicsProtonElectron transferReactivity (psychology)Density functional theoryChemistryElectronQuantumTransition stateMarcus theoryProton-coupled electron transferChemical physicsAtomic physicsComputational chemistryPhysicsPhysical chemistryQuantum mechanicsCatalysisReaction rate constantKineticsMedicinePathologyAlternative medicineBiochemistryMetal-Catalyzed Oxygenation MechanismsCO2 Reduction Techniques and CatalystsPorphyrin and Phthalocyanine Chemistry
Reconciling Imbalanced and Nonadiabatic Reactivity in Transition Metal–Oxo-Mediated Concerted Proton Electron Transfer (CPET) | Litcius