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Autores principales: Ostermann, Stefan, Rubies-Bigorda, Oriol, Zhang, Victoria, Yelin, Susanne F.
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2311.10824
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author Ostermann, Stefan
Rubies-Bigorda, Oriol
Zhang, Victoria
Yelin, Susanne F.
author_facet Ostermann, Stefan
Rubies-Bigorda, Oriol
Zhang, Victoria
Yelin, Susanne F.
contents Recent advances in generating well controlled dense arrangements of individual atoms in free space have generated interest in understanding how the extended nature of these systems influences superradiance phenomena. Here, we provide an in-depth analysis on how space-dependent light-shifts and decay rates induced by dipole-dipole interactions modify the steady-state properties of coherently driven arrays of quantum emitters. We characterize the steady-state phase diagram, with particular focus on the radiative properties in the steady-state. Interestingly, we find that diverging from the well-established Dicke paradigm of equal all-to-all interactions significantly modifies the emission properties. In particular, the prominent quadratic scaling of the radiated light intensity with particle number in the steady-state -- a hallmark of steady-state Dicke superradiance -- is entirely suppressed, resulting in only linear scaling with particle number. We show that this breakdown of steady-state superradiance occurs due to the emergence of additional dissipation channels that populate not only superradiant states but also subradiant ones. The additional contribution of subradiant dark states in the dynamics leads to a divergence in the time scales needed to achieve steady-states. Building on this, we further show that measurements taken at finite times for extended atom ensembles reveal properties closely mirroring the idealized Dicke scenario.
format Preprint
id arxiv_https___arxiv_org_abs_2311_10824
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Breakdown of steady-state superradiance in extended driven atomic arrays
Ostermann, Stefan
Rubies-Bigorda, Oriol
Zhang, Victoria
Yelin, Susanne F.
Quantum Physics
Recent advances in generating well controlled dense arrangements of individual atoms in free space have generated interest in understanding how the extended nature of these systems influences superradiance phenomena. Here, we provide an in-depth analysis on how space-dependent light-shifts and decay rates induced by dipole-dipole interactions modify the steady-state properties of coherently driven arrays of quantum emitters. We characterize the steady-state phase diagram, with particular focus on the radiative properties in the steady-state. Interestingly, we find that diverging from the well-established Dicke paradigm of equal all-to-all interactions significantly modifies the emission properties. In particular, the prominent quadratic scaling of the radiated light intensity with particle number in the steady-state -- a hallmark of steady-state Dicke superradiance -- is entirely suppressed, resulting in only linear scaling with particle number. We show that this breakdown of steady-state superradiance occurs due to the emergence of additional dissipation channels that populate not only superradiant states but also subradiant ones. The additional contribution of subradiant dark states in the dynamics leads to a divergence in the time scales needed to achieve steady-states. Building on this, we further show that measurements taken at finite times for extended atom ensembles reveal properties closely mirroring the idealized Dicke scenario.
title Breakdown of steady-state superradiance in extended driven atomic arrays
topic Quantum Physics
url https://arxiv.org/abs/2311.10824