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The Marcus dimension: identifying the nuclear coordinate for electron transfer from <i>ab initio</i> calculations

Adam Šrut, Benjamin J. Lear, Vera Krewald

2023Chemical Science11 citationsDOIOpen Access PDF

Abstract

approach for quantifying the ET coordinate and demonstrate it for a series of dinitroradical anions. Using sampling methods at finite temperature combined with density functional theory calculations, we find that the electron transfer can be followed using the energy separation between potential energy surfaces and the extent of electron localization. The precise nuclear motion that leads to electron transfer is then obtained as a linear combination of normal modes. Once the coordinate is identified, we find that evolution along it results in a change in diabatic state and optical excitation energy, as predicted by the Marcus model. Thus, we conclude that a single dimension of the electron transfer described in Marcus-Hush theory can be described as a well-defined nuclear motion. Importantly, our approach allows the separation of the intrinsic electron transfer coordinate from other structural relaxations and environmental influences. Furthermore, the barrier separating the adiabatic minima was found to be sufficiently thin to enable heavy-atom tunneling in the ET process.

Topics & Concepts

Dimension (graph theory)Ab initioElectron transferElectronComputational chemistryPhysicsAb initio quantum chemistry methodsChemistryAtomic physicsQuantum mechanicsPure mathematicsMathematicsPhysical chemistryMoleculePhotochemistry and Electron Transfer StudiesAdvanced Chemical Physics StudiesMolecular Junctions and Nanostructures