Optical lattices as a tool to study defect-induced superfluidity

We investigate the superfluid-insulator transition of one-dimensional interacting bosons in both deep and shallow periodic potentials. We compare a theoretical analysis based on quantum Monte Carlo simulations in continuum space and Luttinger liquid approach with experiments on ultracold atoms with tunable interactions and optical lattice depth. Experiments and theory are in excellent agreement. Our study provides a quantitative determination of the critical parameters for the Mott transition and defines the regimes of validity of widely used approximate models, namely, the Bose-Hubbard and sine-Gordon models.

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“…Recently, a preprint appeared reporting the numerical study of the Mott-U transition with results consistent with ours [49].…”

supporting

confidence: 85%

Mott transition for strongly interacting one-dimensional bosons in a shallow periodic potential

et al. 2016

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“…The gas in this phase therefore represents a momentum delocalized superfluid that exhibits some of the distinct characteristics of both the superfluid and the pinned phase. The observed momentum distribution is similar to the momentum distributions found in supersolids [52] and it has recently been suggested that the incommensurate phase of the TG gas in deep lattices is similar to a defect-induced superfluid phase and can be utilized to investigate the Andreev-Lifschitz-Chester mechanism [12,53].…”

Section: Coherence and Momentum Distributionsupporting

confidence: 74%

“…If the deviation from the commensurate phase at F=1 is microscopic, such that N=M±1, the phase becomes gapless with a quadratic dispersion relation. On the other hand, for a macroscopic number of defects, such as N=M±M/2, the phase is also gapless, but with a linear dispersion relation [12]. These regimes are, however, continuously connected which can be seen in figure 4(a), where the momentum distribution as a function of F is plotted for a constant depth = V E 20 r 0 .…”

Section: Coherence and Momentum Distributionmentioning

confidence: 98%

“…In this case, a commensurate particle density leads to an integer filling of each lattice site and thus realizes an insulating pinned phase where dynamics is suppressed due to vanishing long range coherence. For incommensurate particle densities each lattice site has a non-integer filling which has the effect of creating delocalized modes which can be considered as defects [11,12]. These defects promote dynamics as they preserve a degree of coherence and allow the system to attain superfluid-like properties.…”

Section: Introductionmentioning

confidence: 99%

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Static and dynamic phases of a Tonks–Girardeau gas in an optical lattice

2018

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We investigate the properties of a Tonks-Girardeau gas in the presence of a one-dimensional lattice potential. Such a system is known to exhibit a pinning transition when the lattice is commensurate with the particle density, leading to the formation of an insulating state even at infinitesimally small lattice depths. Here we examine the properties of the gas at all lattices depths and, in addition to the static properties, also consider the non-adiabatic dynamics induced by the sudden motion of the lattice potential with a constant speed. Our work provides a continuum counterpart to the work done in discrete lattice models.

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“…4 indicate the strong rotonization of the collective excitation branch near the phase transition. By introducing a small fraction of vacancies one can expect the formation of a quadrupolar supersolid in the strongly interacting regime [38], which is similar to the vacancy-induced Andreev-Lifshitz mechanism [70][71][72][73][74].…”

mentioning

confidence: 92%

Quantum phase transition of a two-dimensional quadrupolar system

et al. 2021

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Ensembles with long-range interactions between particles are promising for revealing strong quantum collective effects and many-body phenomena. Here we study the ground-state phase diagram of a two-dimensional Bose system with quadrupolar interactions using a diffusion Monte Carlo technique. We predict a quantum phase transition from a gas to a solid phase. The Lindemann ratio and the condensate fraction at the transition point are γ = 0.269(4) and n0/n = 0.031(4), correspondingly. We observe the strong rotonization of the collective excitation branch in the vicinity of the phase transition point. Our results can be probed using state-of-the-art experimental systems of various nature, such as quasi-two-dimensional systems of quadrupolar excitons in transition metal dichalcogenide (TMD) tri-layers, quadrupolar molecules, and excitons or Rydberg atoms with quadrupole moments induced by strong magnetic fields.

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Optical lattices as a tool to study defect-induced superfluidity

Cited by 11 publications

References 52 publications

Mott transition for strongly interacting one-dimensional bosons in a shallow periodic potential

Mott transition for strongly interacting one-dimensional bosons in a shallow periodic potential

Static and dynamic phases of a Tonks–Girardeau gas in an optical lattice

Quantum phase transition of a two-dimensional quadrupolar system

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