On the Role of Non-Diagonal System-Environment Interactions in Bridge-Mediated Electron Transfer

TL;DR

This paper investigates how off-diagonal system-environment interactions influence bridge-mediated electron transfer, revealing their significant impact on transfer dynamics, localization, and coherence, using advanced numerical simulations.

Contribution

It provides the first detailed numerical analysis of off-diagonal system-environment interactions in electron transfer, highlighting their role in complex vibronic effects and transfer mechanisms.

Findings

Off-diagonal interactions significantly affect ET dynamics.

These interactions can induce anomalous localization.

Coherent transfer can be facilitated by off-diagonal couplings.

Abstract

Bridge-mediated electron transfer (ET) between a donor and an acceptor is prototypical for the description of numerous most important ET scenarios. While multi-step ET and the interplay of sequential and direct superexchange transfer pathways in the donor-bridge-acceptor (D-B-A) model is increasingly understood, the influence off-diagonal system-bath interactions on the transfer dynamics is less explored. Off-diagonal interactions account for the dependence of the ET coupling elements on nuclear coordinates (non-Condon effects) and are typically neglected. Here we numerically investigate with quasi-adiabatic propagator path integral (QUAPI) simulations the impact of off-diagonal system-environment interactions on the transfer dynamics for a wide range of scenarios in the D-B-A model. We demonstrate that off-diagonal system-environment interactions can have profound impact on the bridge-mediated ET dynamics. In the considered scenarios the dynamics itself does not allow for a rigorous assignment of the underlying transfer mechanism. Further, we demonstrate how off-diagonal system-environment interaction mediates anomalous localization by preventing long-time depopulation of the bridge B and how coherent transfer dynamics between donor D and acceptor A can be facilitated. The arising non-exponential short-time dynamics and coherent oscillations are interpreted within an equivalent Hamiltonian representation of a primary reaction coordinate model that reveals how the complex vibronic interplay of vibrational and electronic degrees of freedom underlying the non-Condon effects can impose donor-to-acceptor coherence transfer on short timescales.