Flexible Rydberg aggregates, assemblies of few Rydberg atoms coherently
sharing electronic excitations while undergoing directed atomic motion, show
great promise as quantum simulation platform for nuclear motional dynamics in
molecules or quantum energy transport. Here we study additional features that
are enabled by the presence of more than a single electronic excitation, thus
considering multi-exciton states. We describe cases where these can be
decomposed into underlying single exciton states and then present dynamical
scenarios with atomic motion that illustrate exciton-exciton collisions,
exciton routing, and strong non-adiabatic effects in simple one-dimensional
settings.Comment: 7 pages, 8 figure

Abumwis, Ghassan

Wüster, Sebastian

English

arXiv

Flexible Rydberg aggregates, assemblies of a few Rydberg atoms coherently sharing electronic excitations while undergoing directed atomic motion, show great promise as a quantum simulation platform for nuclear motion in molecules or quantum energy transport. Here we study additional features that are enabled by the presence of more than a single electronic excitation, thus considering multiexciton states. We describe cases where these can be decomposed into underlying single-exciton states and then present dynamical scenarios with atomic motion that illustrate exciton-exciton collisions, exciton routing, and strong nonadiabatic effects in simple one-dimensional settings.We gratefully acknowledge fruitful discussions with Alexander Eisfeld, and thank the Science and Engineering Research Board (SERB), Department of Science and Technology (DST), New Delhi, India, for financial support under research Project No. EMR/2016/005462. Financial support from the Max-Planck society under the MPG-IISER partner group program is also gratefully acknowledged

Abumwis, G.

Wüster, S.

Bilkent University Institutional Repository

Multiexcitons in flexible Rydberg aggregates

Flexible Rydberg aggregates, assemblies of a few Rydberg atoms coherently sharing electronic excitations while undergoing directed atomic motion, show great promise as a quantum simulation platform for nuclear motion in molecules or quantum energy transport. Here we study additional features that are enabled by the presence of more than a single electronic excitation, thus considering multiexciton states. We describe cases where these can be decomposed into underlying single-exciton states and then present dynamical scenarios with atomic motion that illustrate exciton-exciton collisions, exciton routing, and strong nonadiabatic effects in simple one-dimensional settings

Multi-Excitons in Flexible Rydberg Aggregates

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