Implementing quantum electrodynamics with ultracold atomic systems

Kasper, Valentin; Hebenstreit, Florian; Jendrzejewski, Fred; Oberthaler, Markus K.; Berges, Jürgen

doi:10.1088/1367-2630/aa54e0

Cited by 114 publications

(108 citation statements)

References 76 publications

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“…The MPS method provides a unique means to benchmark quantum simulators of the massive Schwinger model or related models using ultracold ions or atoms in optical lattices [40][41][42][43][44]. On the other hand, it is a major goal to extend this type of real-time simulation technique to more than one spatial dimension using projected entangled pair states (PEPS) [4].…”

Section: Discussionmentioning

confidence: 99%

Real-time simulation of the Schwinger effect with matrix product states

et al. 2017

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Matrix Product States (MPS) are used for the simulation of the real-time dynamics induced by an electric quench on the vacuum state of the massive Schwinger model. For small quenches it is found that the obtained oscillatory behavior of local observables can be explained from the single-particle excitations of the quenched Hamiltonian. For large quenches damped oscillations are found and comparison of the late time behavior with the appropriate Gibbs states seems to give some evidence for the onset of thermalization. Finally, the MPS real-time simulations are compared with results from real-time lattice gauge theory which are expected to agree in the limit of large quenches.

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Section: Discussionmentioning

confidence: 99%

Real-time simulation of the Schwinger effect with matrix product states

et al. 2017

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“…Various ideas for creating dynamical gauge fields have been proposed [5][6][7][8][9][10][11][12][13][14][15][16][17]. Recently the Schwinger model has been simulated in ion chains [18].…”

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confidence: 99%

“…Realization.-There have been numerous proposals for the realization of QLM models [11][12][13][14][15][16][17]53]. Here we introduce a simple scheme (Fig.…”

mentioning

confidence: 99%

Hidden Order and Symmetry Protected Topological States in Quantum Link Ladders

2017

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We show that whereas spin-1/2 one-dimensional U(1) quantum-link models (QLMs) are topologically trivial, when implemented in ladder-like lattices these models may present an intriguing ground-state phase diagram, which includes a symmetry protected topological (SPT) phase that may be readily revealed by analyzing long-range string spin correlations along the ladder legs. We propose a simple scheme for the realization of spin-1/2 U(1) QLMs based on single-component fermions loaded in an optical lattice with s-and p-bands, showing that the SPT phase may be experimentally realized by adiabatic preparation.The realization of lattice gauge models using ultra cold gases has attracted a major theoretical attention in recent years [1][2][3][4]. Various ideas for creating dynamical gauge fields have been proposed [5][6][7][8][9][10][11][12][13][14][15][16][17]. Recently the Schwinger model has been simulated in ion chains [18]. Particular interest has been devoted to quantum-link models (QLMs) [19], which generalize lattice gauge theory [20] by realizing continuous gauge symmetries with discrete gauge variables (quantum links). QLMs are relevant in particle physics, and in particular QCD [21], and in condensed matter physics [22,23]. In U(1) QLMs, links are represented by quantum spins and fermions provide the matter field, making these QLMs particularly suitable for simulation with cold lattice gases.In this Letter we study the topological properties of spin-1/2 U(1) QLMs. Topological quantum systems have become one of the most active research areas during the past decades [24,25]. In particular the understanding of topological phases in strongly correlated quantum systems remains challenging. The study of symmetry protected topological (SPT) states has triggered a large progress in this field [26]. SPT phases have been classified by means of entanglement properties and group theoretical considerations [27][28][29][30][31][32]. Indeed in onedimensional (1D) systems, SPT phases are the only realizable class of topological quantum states, a prominent example being the so-called Haldane phase of odd-integer spin chains [33,34]. Generalizations of the Haldane phase have been theoretically studied in the context of ultracold gases [35][36][37][38][39][40].Real or synthetic ladder-like lattices have recently constituted the focus of major efforts [41][42][43] in the context of the realization of static gauge fields in ultra-cold atomic systems. We show below that although in 1D spin-1/2 U(1) QLMs are topologically trivial, when implemented in ladder-like lattices these models present an intriguing ground-state phase diagram, which interestingly includes an SPT phase that we characterize using a generalized topological order parameter and the entanglement spectrum. We show that the SPT phase may be revealed by analyzing string spin correlations along the ladder legs. Moreover, we propose a simple scheme for the realization of the QLM based on s-p lattices [44], showing that the SPT phase may be experimentally realized by adiab...

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“…Future cold atom experiments with repulsively interacting fermions could probe this 'excitionic' shift as well, allowing more quantitative comparison with higher order corrections to the threshold field strength. In addition, the pair-creation phenomena occurring in strongly interacting field theories, even absent applied electric fields, may also be realized using mixtures of ultracold bosons and fermions [9,10] and has already been realized using trapped ions [44].…”

Section: Discussionmentioning

confidence: 99%

“…Electric fields on this scale are not experimentally accessible; even the largest laboratory fields produced by ultrashort laser pulses [6] fall short, making direct observation of pair creation out of reach of current experiments. Subsequently, analog experiments have been proposed that simulate high-field effects with laboratory accessible energy scales in cold atoms [7][8][9][10], graphene [11][12][13][14][15][16], and other condensed matter systems [12,[17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Sauter–Schwinger effect with a quantum gas

Piñeiro

Genkina

et al. 2019

New J. Phys.

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The creation of particle-antiparticle pairs from vacuum by a large electric field is at the core of quantum electrodynamics. Despite the wide acceptance that this phenomenon occurs naturally when electric field strengths exceed E c ≈10 18 V m −1 , it has yet to be experimentally observed due to the limitations imposed by producing electric fields at this scale. The high degree of experimental control present in ultracold atomic systems allow experimentalists to create laboratory analogs to high-field phenomena. Here we emulated massive relativistic particles subject to large electric field strengths, thereby quantum-simulated particle-antiparticle pair creation, and experimentally explored particle creation from 'the Dirac vacuum'. Data collected from our analog system spans the full parameter regime from low applied field (negligible pair creation) below the Sauter-Schwinger limit, to high field (maximum rate of pair creation) far in excess of the Sauter-Schwinger limit. In our experiment, we perform direct measurements on an analog atomic system and show that this high-field phenomenon is well-characterized by Landau-Zener tunneling, well known in the atomic physics context, and we find full quantitative agreement with theory with no adjustable parameters.

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Implementing quantum electrodynamics with ultracold atomic systems

Cited by 114 publications

References 76 publications

Real-time simulation of the Schwinger effect with matrix product states

Real-time simulation of the Schwinger effect with matrix product states

Hidden Order and Symmetry Protected Topological States in Quantum Link Ladders

Sauter–Schwinger effect with a quantum gas

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