Realization of an Excited, Strongly Correlated Quantum Gas Phase

We investigate the dynamical properties of anyons confined in one-dimensional optical lattice combined with a weak harmonic trap using the exact numerical method based on a generalized Jordan-Wigner transformation. The density profiles, momentum distribution, occupation distribution and occupations of the lowest natural orbital are obtained for different statistical parameters. The density profiles of anyons display the same behaviors irrespective of statistical parameter in the full evolving period. While the behaviors dependent on statistical property are shown in the momentum distributions and occupations of natural orbitals.

Section: Introductionmentioning

confidence: 99%

Dynamical properties of hard-core anyons in one-dimensional optical lattices

Hao

Chen

2012

“…In these extremely sophisticated experiments it is possible to control the total number of particles, their mutual interactions, and the shape of external potential with very high accuracies [3][4][5][6][7]. As a consequence, a deep analysis of many properties of one-dimensional few-body systems is performed experimentally.…”

Section: Introductionmentioning

confidence: 99%

Few strongly interacting ultracold fermions in one-dimensional traps of different shapes

Pęcak

Sowiński

2016

The ground-state properties of a few spin-1/2 fermions with different masses and interacting via short-range contact forces are studied within an exact diagonalization approach. It is shown that, depending on the shape of the external confinement, different scenarios of the spatial separation between components manifested by specific shapes of the density profiles can be obtained in the strong interaction limit. We find that the ground-state of the system undergoes a specific transition between orderings when the confinement is changed adiabatically from a uniform box to a harmonic oscillator shape. We study the properties of this transition in the framework of the finite-size scaling method adopted to few-body systems.

“…The degenerate regime is achieved for atomic densities n larger than or of the order of a D−3 ⊥ /λ D T where λ T is the de Broglie wavelength. The limit of Tonks-Girardeau and super TonksGirardeau [7,8] are two celebrated examples of highly correlated 1D phase which have been achieved thanks to ultra-cold atoms experiments [9][10][11]. In the 2D geometry the interplay between the Bose-Einstein condensate (BEC) and the Berezinskii-Kosterlitz-Thouless (BKT) transitions has been subject to intensive experimental studies [12,13].…”

Section: Introductionmentioning

confidence: 99%

Ultracold-atom collisions in atomic waveguides: A two-channel analysis

Kristensen

Pricoupenko

2015

Low dimensional behavior of two ultra-cold atoms trapped in two-and one-dimensional waveguides is investigated in the vicinity of a magnetic Feshbach resonance. A quantitative two-channel model for the Feshbach mechanism is used, allowing an exhaustive analysis of low-dimensional resonant scattering behavior and of the confinement induced bound states. The role of the different parameters of the resonance is depicted in this context. Results are compared with the ones of the zero-range approach. The relevance of the effective range approximation in low dimensions is studied. Examples of known resonances are used to illustrate the bound state properties.