Instanton Theory for Nonadiabatic Tunneling through Near-Barrier Crossings

TL;DR

This paper extends instanton theory to model nonadiabatic tunneling near diabatic barriers, providing a new semiclassical approach for reactions involving multiple electronic states and competing pathways.

Contribution

The authors develop a novel extension of instanton theory to describe non-convex tunneling pathways in nonadiabatic reactions, filling a gap in existing rate theories.

Findings

Rates agree with quantum-mechanical FGR calculations

Provides insights into multi-step tunneling reactions

Reveals competition between sequential and concerted pathways

Abstract

Many reactions in chemistry and biology involve multiple electronic states, rendering them nonadiabatic in nature. These reactions can be formally described using Fermi's golden rule (FGR) in the weak-coupling limit. Nonadiabatic instanton theory presents a semiclassical approximation to FGR, which is directly applicable to molecular systems. However, there are cases where the theory has not yet been formulated. For instance, in many real-world reactions including spin-crossover or proton-coupled electron transfer, the crossing occurs near a barrier on a diabatic state. This scenario gives rise to competing nonadiabatic reaction pathways, some of which involve tunneling through a diabatic barrier while simultaneously switching electronic states. To date, no rate theory is available for describing tunneling via these unconventional pathways. Here we extend instanton theory to model this class of processes, which we term the ``non-convex'' regime. Benchmark tests on model systems show that the rates predicted by instanton theory are in excellent agreement with quantum-mechanical FGR calculations. Furthermore, the method offers new insights into multi-step tunneling reactions and the competition between sequential and concerted nonadiabatic tunneling pathways.