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Main Authors: Gjonbalaj, Nik O., Ostermann, Stefan, Yelin, Susanne F.
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2309.04384
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author Gjonbalaj, Nik O.
Ostermann, Stefan
Yelin, Susanne F.
author_facet Gjonbalaj, Nik O.
Ostermann, Stefan
Yelin, Susanne F.
contents Atomic arrays can exhibit collective light emission when the transition wavelength exceeds their lattice spacing. Subradiant states take advantage of this phenomenon to drastically reduce their overall decay rate, allowing for long-lived states in dissipative open systems. We build on previous work to investigate whether or not disorder can further decrease the decay rate of a singly-excited atomic array. More specifically, we consider spatial disorder of varying strengths in a 1D half waveguide and in 1D, 2D, and 3D atomic arrays in free space and analyze the effect on the most subradiant modes. While we confirm that the dilute half waveguide exhibits an analog of Anderson localization, the dense half waveguide and free space systems can be understood through the creation of close-packed, few-body subradiant states similar to those found in the Dicke limit. In general, we find that disorder provides little advantage in generating darker subradiant states in free space on average and will often accelerate decay. However, one could potentially change interatomic spacing within the array to engineer specific subradiant states.
format Preprint
id arxiv_https___arxiv_org_abs_2309_04384
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Modifying cooperative decay via disorder in atom arrays
Gjonbalaj, Nik O.
Ostermann, Stefan
Yelin, Susanne F.
Quantum Physics
Atomic arrays can exhibit collective light emission when the transition wavelength exceeds their lattice spacing. Subradiant states take advantage of this phenomenon to drastically reduce their overall decay rate, allowing for long-lived states in dissipative open systems. We build on previous work to investigate whether or not disorder can further decrease the decay rate of a singly-excited atomic array. More specifically, we consider spatial disorder of varying strengths in a 1D half waveguide and in 1D, 2D, and 3D atomic arrays in free space and analyze the effect on the most subradiant modes. While we confirm that the dilute half waveguide exhibits an analog of Anderson localization, the dense half waveguide and free space systems can be understood through the creation of close-packed, few-body subradiant states similar to those found in the Dicke limit. In general, we find that disorder provides little advantage in generating darker subradiant states in free space on average and will often accelerate decay. However, one could potentially change interatomic spacing within the array to engineer specific subradiant states.
title Modifying cooperative decay via disorder in atom arrays
topic Quantum Physics
url https://arxiv.org/abs/2309.04384