Measurement and simulation of atomic motion in nanoscale optical trapping potentials

Markussen, Signe B.; Appel, J.; Østfeldt, Christoffer; Béguin, Jean-Baptiste S.; Polzik, E. S.; Müller, J. H.

doi:10.1007/s00340-020-07424-5

Cited by 8 publications

(4 citation statements)

References 17 publications

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“…In spite of the close vicinity of the nanofiber surface, ground-state decoherence times on the order of milliseconds have been experimentally demonstrated for nanofiber-coupled atoms [14]. Experiments employing a Λ-type level structure in this setting include, e.g., EIT-based light storage [15,16], Raman cooling [17,18], generation of single collective excitations [19], probing of the in-trap atomic motion [20], and non-reciprocal Raman amplification [21].…”

Section: Introductionmentioning

confidence: 99%

Observation of oscillatory Raman gain associated with two-photon Rabi oscillations of nanofiber-coupled atoms

Liedl

Pucher

Schneeweiß

et al. 2022

J. Phys. B: At. Mol. Opt. Phys.

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Quantum emitters with a Λ-type level structure enable numerous protocols and applications in quantum science and technology. Understanding and controlling their dynamics is, therefore, one of the central research topics in quantum optics. Here, we drive two-photon Rabi oscillations between the two ground states of cesium atoms and observe the associated oscillatory Raman gain and absorption that stems from the atom-mediated coherent photon exchange between the two drive ﬁelds. The atoms are eﬃciently and homogeneously coupled with the probe ﬁeld by means of a nanoﬁber-based optical interface. We study the dependence of the two-photon Rabi frequency on the system parameters and observe Autler-Townes splitting in the probe transmission spectrum. Beyond shedding light on the fundamental processes underlying two-photon Rabi oscillations, our method could also be used to investigate (quantum) correlations between the two drive ﬁelds as well as the dynamical establishment of electromagnetically induced transparency.

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Section: Introductionmentioning

confidence: 99%

Observation of oscillatory Raman gain associated with two-photon Rabi oscillations of nanofiber-coupled atoms

Liedl

Pucher

Schneeweiß

et al. 2022

J. Phys. B: At. Mol. Opt. Phys.

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show abstract

“…Once trapped, the atoms interact with the evanescent field of light modes propagating within the fiber [5], exchanging energy and momentum. Thus, the light strongly influences the atomic motion in the trap which in turn modifies the light propagation [7][8][9][10]. As photons within the fiber propagate over practically infinite distances, they collectively couple to all atoms, which induces all-to-all long-range interactions [11].…”

Section: Introductionmentioning

confidence: 99%

A Versatile Quantum Simulator for Coupled Oscillators Using a 1D Chain of Atoms Trapped near an Optical Nanofiber

2021

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The transversely confined propagating light modes of a nanophotonic optical waveguide or nanofiber can effectively mediate infinite-range forces. We show that for a linear chain of particles trapped within the waveguide’s evanescent field, transverse illumination with a suitable set of laser frequencies should allow the implementation of a coupled-oscillator quantum simulator with time-dependent and widely controllable all-to-all interactions. Using the example of the energy spectrum of oscillators with simulated Coulomb interactions, we show that different effective coupling geometries can be emulated with high precision by proper choice of laser illumination conditions. Similarly, basic quantum gates can be selectively implemented between arbitrarily chosen pairs of oscillators in the energy as well as in the coherent-state basis. Key properties of the system dynamics and states can be monitored continuously by analysis of the out-coupled fiber fields.

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“…Once trapped, the atoms interact with the evanescent field of light modes propagating within the fiber [5] exchanging energy and momentum. Thus the light strongly influences the atomic motion in the trap which in turn modifies the light propagation [6,7,8,9]. As photons within the fiber propagate over practically infinite distances they collectively couple to all atoms, which induces all-to-all long-range interactions [10].…”

Section: Introductionmentioning

confidence: 99%

A versatile quantum simulator for coupled oscillators using a 1D chain of atoms trapped near an optical nanofiber

Holzmann¹,

Sonnleitner²,

Ritsch³

2021

Preprint

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The transversely confined propagating light modes of a nano-photonic optical waveguide or nanofiber can mediate effectively infinite-range forces. We show that for a linear chain of particles trapped within the waveguide's evanescent field, transverse illumination with a suitable set of laser frequencies should allow the implementation of a coupled-oscillator quantum simulator with time-dependent and widely controllable all-to-all interactions. At the example of the energy spectrum of oscillators with simulated Coulomb interactions we show that different effective coupling geometries can be emulated with high precision by proper choice of laser illumination conditions. Similarly, basic quantum gates can be selectively implemented between arbitrarily chosen pairs of oscillators in the energy basis as well as in a coherent-state basis. Key properties of the system dynamics and states can be monitored continuously by analysis of the out-coupled fiber fields.

show abstract

Measurement and simulation of atomic motion in nanoscale optical trapping potentials

Cited by 8 publications

References 17 publications

Observation of oscillatory Raman gain associated with two-photon Rabi oscillations of nanofiber-coupled atoms

Observation of oscillatory Raman gain associated with two-photon Rabi oscillations of nanofiber-coupled atoms

A Versatile Quantum Simulator for Coupled Oscillators Using a 1D Chain of Atoms Trapped near an Optical Nanofiber

A versatile quantum simulator for coupled oscillators using a 1D chain of atoms trapped near an optical nanofiber

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