Coherent Population Trapping with Controlled Interparticle Interactions

Schempp, H.; Günter, G.; Hofmann, Christoph; Giese, Christian; Saliba, S. D.; DePaola, B. D.; Amthor, Thomas; Weidemüller, Matthias; Sevinçli, S.; Pohl, Thomas

doi:10.1103/physrevlett.104.173602

Cited by 100 publications

(131 citation statements)

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“…Such three-level excitation schemes are utilised in numerous Rydberg atom experiments, either exploring interaction effects in the strong excitation regime (Ω 1 > Ω 2 ) [33][34][35][36] or quantum optics applications in the opposite limit [37][38][39][40]. As a specific example, laser excitation of Rb(35S 1/2 ) Rydberg states via the intermediate Rb(5P 1/2 ) state with Ω 1 = 0.5γ = 4Ω 2 yields p 0 ≈ 0.9, upon accounting for the small but nonnegligible Rydberg state decay.…”

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confidence: 99%

Antiferromagnetic long-range order in dissipative Rydberg lattices

et al. 2014

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We study the dynamics of dissipative spin lattices with power-law interactions, realized via fewlevel atoms driven by coherent laser-coupling and decoherence processes. Using Monte-Carlo simulations, we determine the phase diagram in the steady state and analyze the dynamics of its generation. As opposed to mean-field predictions and nearest-neighbour models there is no phase transition to long-range ordered phases for realistic interactions and resonant driving. However, for finite laser detunings, we demonstrate the emergence of crystalline order with a vanishing dissipative gap. Although the found steady states differ considerably from those of an equilibrium Ising magnet, the critical exponent of the revealed dissipative phase transition falls into the 2D Ising universality class. Two complementary schemes for an experimental implementation with cold Rydberg atoms are discussed. [5][6][7]. This requires sufficient time to remain adiabatic, which poses a challenging competition with the finite lifetime of the Rydberg states. Alternatively, this excited-state decay has been proposed as a natural means for dissipative state preparation [8]. The non-equilibrium physics of such driven open systems has recently attracted considerable interest [9][10][11][12], as their properties can differ dramatically from conventional equilibrium situations.Previous work considered lattices of effective spins, represented by an atomic ground and strongly interacting Rydberg state coupled by external laser driving and spontaneous decay [8,13,14]. The emergence of steady states with antiferromagnetic order was predicted on the basis of mean field theory assuming nearest-neighbour (NN) interactions [8]. It was later shown, however, that ordering in these systems is restricted to short length scales for all spatial lattice dimensions due to large singlesite fluctuations associated with a simple two-level driving scheme [14]. Simulations moreover showed that crystallization in 1D is precluded for other driving schemes [14], for which long-range order was predicted using mean field theory [15]. Hence, the possibility of long-range order in dissipative Rydberg lattices has thus far remained an open question.In this letter, we address this issue and show that longrange ordered antiferromagnetic phases can indeed be re- alized in dissipative Rydberg lattices when subject to appropriate coherent driving. However, fluctuations as well as the weak tail of the rapidly decaying interactions are both found to be essential for the physics of the dissipative phase transition. This stands in marked contrast to the equilibrium physics of the corresponding unitary systems, which often is well described by mean field models [16] and NN approximations [17]. The crystalline phase features a vanishing dissipative gap and strongly deviates from that of an equilibrium Ising magnet with finite arXiv:1404.1281v1 [cond-mat.quant-gas]

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Antiferromagnetic long-range order in dissipative Rydberg lattices

et al. 2014

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“…In this regime, which has been studied experimentally in Refs. [33,34,35,36,37,38,39], atoms are modelled by coherently driven and interacting three-level systems. Dissipation enters through a fast (radiative) decay of the middle level to the lower one.…”

Section: Introductionmentioning

confidence: 99%

Effective dynamics of strongly dissipative Rydberg gases

Marcuzzi¹,

Schick²,

Olmos³

et al. 2014

J. Phys. A: Math. Theor.

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Abstract. We investigate the evolution of interacting Rydberg gases in the limit of strong noise and dissipation. Starting from a description in terms of a Markovian quantum master equation we derive effective equations of motion that govern the dynamics on a "coarse-grained" timescale where fast dissipative degrees of freedom have been adiabatically eliminated. Specifically, we consider two scenarios which are of relevance for current theoretical and experimental studies -Rydberg atoms in a twolevel (spin) approximation subject to strong dephasing noise as well as Rydberg atoms under so-called electromagnetically induced transparency (EIT) conditions and fast radiative decay. In the former case we find that the effective dynamics is described by classical rate equations up to second order in an appropriate perturbative expansion. This drastically reduces the computational complexity of numerical simulations in comparison to the full quantum master equation. When accounting for the fourth order correction in this expansion, however, we find that the resulting equation breaks the preservation of positivity and thus cannot be interpreted as a proper classical master rate equation. In the EIT system we find that the expansion up to second order retains information not only on the "classical" observables, but also on some quantum coherences. Nevertheless, this perturbative treatment still achieves a nontrivial reduction of complexity with respect to the original problem.

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“…8 (a), with: |1 ≡ |5S 1/2 , F = 2 , |2 ≡ |5P 3/2 , F = 3 , and |3 ≡ |40S 1/2 . For simplicity we moreover restrict ourselves to a regime of experimental parameters in which Rydberg-Rydberg interaction effects on the EIT can be neglected [60][61][62]. We prepare a cigar shaped Gaussian cloud (σ radial = 75± 3 µm, σ axial = 280±10 µm) with N ≈ 2.4×10 5 atoms and a peak atomic density ρ = 2.2×10 9 cm −3 .…”

Section: Rydberg Atom Detectionmentioning

confidence: 99%

An experimental approach for investigating many-body phenomena in Rydberg-interacting quantum systems

et al. 2013

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Recent developments in the study of ultracold Rydberg gases demand an advanced level of experimental sophistication, in which high atomic and optical densities must be combined with excellent control of external fields and sensitive Rydberg atom detection. We describe a tailored experimental system used to produce and study Rydberg-interacting atoms excited from dense ultracold atomic gases. The experiment has been optimized for fast duty cycles using a high flux cold atom source and a three beam optical dipole trap. The latter enables tuning of the atomic density and temperature over several orders of magnitude, all the way to the Bose-Einstein condensation transition. An electrode structure surrounding the atoms allows for precise control over electric fields and single-particle sensitive field ionization detection of Rydberg atoms. We review two experiments which highlight the influence of strong Rydberg-Rydberg interactions on different many-body systems. First, the Rydberg blockade effect is used to pre-structure an atomic gas prior to its spontaneous evolution into an ultracold plasma. Second, hybrid states of photons and atoms called dark-state polaritons are studied. By looking at the statistical distribution of Rydberg excited atoms we reveal correlations between dark-state polaritons. These experiments will ultimately provide a deeper understanding of many-body phenomena in strongly-interacting regimes, including the study of strongly-coupled plasmas and interfaces between atoms and light at the quantum level.

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Coherent Population Trapping with Controlled Interparticle Interactions

Cited by 100 publications

References 28 publications

Antiferromagnetic long-range order in dissipative Rydberg lattices

Antiferromagnetic long-range order in dissipative Rydberg lattices

Effective dynamics of strongly dissipative Rydberg gases

An experimental approach for investigating many-body phenomena in Rydberg-interacting quantum systems

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