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Competing quantum effects in heavy-atom tunnelling through conical intersections

Wei Fang, Eric R. Heller, Jeremy O. Richardson

2023Chemical Science18 citationsDOIOpen Access PDF

Abstract

Thermally activated chemical reactions are typically understood in terms of overcoming potential-energy barriers. However, standard rate theories break down in the presence of a conical intersection (CI) because these processes are inherently nonadiabatic, invalidating the Born-Oppenheimer approximation. Moreover, CIs give rise to intricate nuclear quantum effects such as tunnelling and the geometric phase, which are neglected by standard trajectory-based simulations and remain largely unexplored in complex molecular systems. We present new semiclassical transition-state theories based on an extension of golden-rule instanton theory to describe nonadiabatic tunnelling through CIs and thus provide an intuitive picture for the reaction mechanism. We apply the method in conjunction with first-principles electronic-structure calculations to the electron transfer in the bis(methylene)-adamantyl cation. Our study reveals a strong competition between heavy-atom tunnelling and geometric-phase effects.

Topics & Concepts

Quantum tunnellingConical surfaceAtom (system on chip)Conical intersectionQuantumPhysicsQuantum mechanicsMoleculeGeometryEngineeringMathematicsEmbedded systemCold Atom Physics and Bose-Einstein CondensatesAdvanced Chemical Physics StudiesAtomic and Molecular Physics