Interplay of excitation transport and atomic motion in flexible Rydberg aggregates

TL;DR

This paper explores how exciton pulses in flexible Rydberg aggregates can be coherently split and controlled via nonadiabatic effects at conical intersections, enabling new insights into quantum dynamics and entanglement transport.

Contribution

It demonstrates the coherent splitting of exciton pulses using nonadiabatic effects at conical intersections in Rydberg aggregates, including realistic anisotropic interactions.

Findings

Pulse splitting observed in planar aggregates with constrained motion.

Conical intersections control exciton propagation and coherence.

Splitting mechanism confirmed in fully realistic anisotropic scenarios.

Abstract

Strong resonant dipole-dipole interactions in flexible Rydberg aggregates enable the formation of exciton pulses, the interplay of atomic motion and electronic excitation transfer which feature high fidelity entanglement transport. Here, we demonstrate the coherent splitting of such pulses into two modes, which induce strongly different atomic motion, leading to clear signatures of nonadiabatic effects in atomic density profiles. The mechanism exploits local nonadiabatic effects at a conical intersection, turning them from a decoherence source into an asset. The conical intersection is a consequence of the exciton pulses moving along a linear Rydberg chain and approaching an additional linear, perpendicularly aligned Rydberg chain. The intersection provides a sensitive knob controlling the propagation direction and coherence properties of exciton pulses. We demonstrate that this scenario can be exploited as an exciton switch, controlling direction and coherence properties of the joint pulse on the second of the chains. Initially, we demonstrate the pulse splitting on planar aggregates with atomic motion one-dimensionally constrained and employing isotropic interactions. Subsequently, we confirm the splitting mechanism for a fully realistic scenario in which all spatial restrictions are removed and the full anisotropy of the dipole-dipole interactions is taken into account. Our results enable the experimental observation of non-adiabatic electronic dynamics and entanglement transport with Rydberg atoms. The conical intersection crossings are clearly evident, both in atomic mean position information and excited state spectra of the Rydberg system. This suggests flexible Rydberg aggregates as a test-bench for quantum chemical effects in experiments on much-inflated length scales. The fundamental ideas discussed here have general implications for excitons on a dynamic network.