Effective normal modes identify vibrational motions which maximally promote vibronic mixing in excitonically coupled aggregates

Controlling energy transfer through vibronic resonance is an interesting possibility. Exact treatment of non-adiabatic vibronic coupling is necessary to fully capture its role in driving energy transfer. However, the exact treatment of vibrations in extended systems is expensive, sometimes requiring oversimplifying approximations to reduce vibrational dimensionality, and do not provide physical insights into which specific vibrational motions promote energy transfer. In this communication, we derive effective normal modes for understanding vibronically enhanced energy transfer in excitonically coupled aggregates. We show that the dynamics of the overall high-dimensional vibronic Hamiltonian can be better understood through one-dimensional Hamiltonians separable along these effective modes. We demonstrate this approach on a trimer toy model to analyze the role of an intermediate trap site in mediating energy transfer between electronically uncoupled sites. Bringing uncoupled sites into vibronic resonance converts the trap into a shuttle for energy transfer. By deconvolving the dynamics along the aggregate normal modes, our approach identifies the specific vibrational motions, which maximally promote energy transfer, against spectator modes, which do not participate in vibronic mixing.

Automated summary

This paper investigates the role of vibronic resonance in energy transfer and proposes a method to better understand vibronically enhanced energy transfer through effective normal modes. The study finds that bringing uncoupled sites into vibronic resonance can convert traps into shuttles for energy transfer.