Subradiance-protected excitation transport

Needham, Jemma A.; Lesanovsky, Igor; Olmos, Beatriz

doi:10.1088/1367-2630/ab31e8

Cited by 65 publications

(31 citation statements)

References 88 publications

(132 reference statements)

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“…7, where we plot the surviving amplitude P = j,µ |P (j) µ | 2 as a function of time for varying fluctuation lengths. For increasing disorder, the excitation decays more quickly, as also observed in other subradiance-protected excitation transfer studies [72]. However, in these cases the lifetime is still much longer than the corresponding case of an in-phase in-plane localized excitation with no disorder.…”

Section: E the Effects Of Position Fluctuationssupporting

confidence: 74%

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Subradiance-protected excitation spreading in the generation of collimated photon emission from an atomic array

Ballantine

2020

Phys. Rev. Research

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We show how an initial localized radiative excitation in a two-dimensional array of cold atoms can be converted into highly-directional coherent emission of light by protecting the spreading of the excitation across the array in a subradiant collective eigenmode with a lifetime orders of magnitude longer than that of an isolated atom. The excitation, which can consist of a single photon, is then released from the protected subradiant eigenmode by controlling the Zeeman level shifts of the atoms. Hence, an original localized excitation which emits in all directions is transferred to a delocalized subradiance-protected excitation, with a probabilistic emission of a photon only along the axis perpendicular to the plane of the atoms. This protected spreading and directional emission could potentially be used to link stages in a quantum information or quantum computing architecture. arXiv:1909.01912v2 [cond-mat.quant-gas]

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Section: E the Effects Of Position Fluctuationssupporting

confidence: 74%

“…Due to the isolation from the environment, subradiant modes have been shown to be useful in transport of excitations [64][65][66][67]. Recent work has explored light transport for closely spaced atoms in arrays with topological edge states [68,69] and in a onedimensional (1D) chain or ring [70][71][72].…”

Section: Introductionmentioning

confidence: 99%

Subradiance-protected excitation spreading in the generation of collimated photon emission from an atomic array

Ballantine

2020

Phys. Rev. Research

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“…In this way, the interferences can be tailored, making it possible to enhance or suppress the effect of dipole interactions. This second route could pave the way to several applications: for example, mirrors made by an atomic * antoine.glicenstein@institutoptique.fr layer [16][17][18], as recently realized using a two-dimensional (2D) Mott insulator [5], controlled transport of excitations [19,20], and light storage [13,21] or in quantum metrology [12,13,22]. The investigation of collective effects in ordered ensembles is also relevant for optical lattice clocks [9,10,23], as they could limit their accuracy.…”

Section: Introductionmentioning

confidence: 99%

Preparation of one-dimensional chains and dense cold atomic clouds with a high numerical aperture four-lens system

et al. 2021

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We report the efficient and fast (∼2 Hz) preparation of randomly loaded one-dimensional (1D) chains of individual 87 Rb atoms and of dense atomic clouds trapped in optical tweezers using an upgraded experimental platform. This platform is designed for the study of atomic ensembles featuring either ordered or disordered distributions of the atomic positions. It is composed of two high-resolution optical systems perpendicular to each other, enhancing observation and manipulation capabilities. The setup includes a dynamically controllable telescope, which we use to vary the tweezer beam waist. A -enhanced gray molasses on the D1 line enhances the loading of the traps from a magneto-optical trap. Using these tools, we prepare chains of up to ∼100 atoms separated by ∼1 μm by retroreflecting the tweezer light, hence producing a 1D optical lattice with strong transverse confinement. Dense atomic clouds with peak densities up to n 0 ∼ 10 15 atoms/cm 3 are obtained by compression of an initial cloud. This high density results in interatomic distances smaller than λ/(2π ) for the D2 optical transitions, making it ideal to study light-induced interactions in dense samples.

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“…Correlations can emerge even for the classical optical regime in the limit of low light intensity (LLI) of an incident laser [21,22], and the quest for observing the effects of strong light-mediated interactions is attracting considerable attention [23][24][25][26][27][28][29][30][31][32][33][34]. Regular arrays of atoms are particularly interesting for the exploration and manipulation of collective optical responses, as more recently studied also in the quantum regime [35][36][37][38][39][40][41][42][43][44][45][46][47]. Transmission-resonance narrowing due to collective subradiance in the classical limit in a planar optical lattice was already observed [48] and other related experiments are rapidly emerging [49].…”

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confidence: 99%

Superatom Picture of Collective Nonclassical Light Emission and Dipole Blockade in Atom Arrays

2020

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We show that two-time, second-order correlations of scattered photons from planar arrays and chains of atoms display nonclassical features that can be described by a superatom picture of the canonical singleatom g 2 ðτÞ resonance fluorescence result. For the superatom, the single-atom linewidth is replaced by the linewidth of the underlying collective low light-intensity eigenmode. Strong light-induced dipole-dipole interactions lead to a correlated response, suppressed joint photon detection events, and dipole blockade that inhibits multiple excitations of the collective atomic state. For targeted subradiant modes, the nonclassical nature of emitted light can be dramatically enhanced even compared with that of a single atom.

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Subradiance-protected excitation transport

Cited by 65 publications

References 88 publications

Subradiance-protected excitation spreading in the generation of collimated photon emission from an atomic array

Subradiance-protected excitation spreading in the generation of collimated photon emission from an atomic array

Preparation of one-dimensional chains and dense cold atomic clouds with a high numerical aperture four-lens system

Superatom Picture of Collective Nonclassical Light Emission and Dipole Blockade in Atom Arrays

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