Quantum dynamics of bosons in a double-well potential: Josephson oscillations, self-trapping and ultralong tunneling times

Salgueiro, A. N.; Piza, A. F. R. de Toledo; Lemos, Gabriela Barreto; Drumond, Raphael C.; Nemes, M. C.; Weidemüller, Matthias

doi:10.1140/epjd/e2007-00224-4

Cited by 53 publications

(74 citation statements)

References 29 publications

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“…7. Their energy splitting in this two-mode model has been determined to be ω [34]. The tunnel period is thus expected to grow exponentially with the number of particles, as already foreshadowed in Fig.…”

Section: Higher Atom Numbersmentioning

confidence: 64%

Interspecies tunneling in one-dimensional Bose mixtures

2010

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We study the ground-state properties and quantum dynamics of few-boson mixtures with strong interspecies repulsion in one-dimensional traps. If one species localizes at the center, e.g., due to a very large mass compared to the other component, it represents an effective barrier for the latter, and the system can be mapped onto identical bosons in a double well. For weaker localization, the barrier atoms begin to respond to the light component, leading to an induced attraction between the mobile atoms that may even outweigh their bare intraspecies repulsion. To explain the resulting effects, we derive an effective Hubbard model for the lighter species accounting for the back action of the barrier in correction terms to the lattice parameters. Also the tunneling is drastically affected: by varying the degree of localization of the "barrier" atoms, the dynamics of intrinsically noninteracting bosons can change from Rabi oscillations to effective pair tunneling. For identical fermions (or fermionized bosons), this leads to the tunneling of attractively bound pairs.

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Section: Higher Atom Numbersmentioning

confidence: 64%

Interspecies tunneling in one-dimensional Bose mixtures

2010

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“…The classical calculation (black solid line) exhibits oscillations in (a) and self-trapping in (b) (note the changed scale for the ordinate). The quantum many-body calculation features the same qualitative behavior, but the oscillations decay due to quantum fluctuations [35].…”

Section: B Bi-species Spin-coherent Statesmentioning

confidence: 71%

“…Since the scaling of will also be discussed, we keep as an explicit parameter. Equation (1) represents a self-trapping equation [31,32], which has been studied extensively [6,10,11,15,30,[33][34][35]. We review here the essential properties that will be useful for our analysis of the two-component case; in particular, we discuss a nonlinear scaling property for the population imbalance between the wells.…”

Section: Single-species Gross-pitaevskii Equation and Nonlinear Smentioning

confidence: 99%

Dynamical effects of exchange symmetry breaking in mixtures of interacting bosons

2012

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In a double-well potential, a Bose-Einstein condensate exhibits Josephson oscillations or self-trapping, depending on its initial preparation and on the ratio of interparticle interaction to interwell tunneling. Here, we elucidate the role of the exchange symmetry for the dynamics with a mixture of two distinguishable species with identical physical properties, that is, which are governed by an isospecific interaction and external potential. In the mean-field limit, the spatial population imbalance of the mixture can be described by the dynamics of a single species in an effective potential with modified properties or, equivalently, with an effective total particle number. The oscillation behavior can be tuned by populating the second species while maintaining the spatial population imbalance and all other parameters constant. In the corresponding many-body approach, the single-species description approximates the full counting statistics well also outside the realm of spin-coherent states. The method is extended to general Bose-Hubbard systems and to their classical mean-field limits, which suggests an effective single-species description of multicomponent Bose gases with weakly an-isospecific interactions.

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“…Theoretically, the tunneling dynamics of single species through the crossover from weak to strong interaction regimes reveal interesting effects such as Josephson oscillations, pair tunneling, self-trapping, and fermionization [29][30][31][32][33], which have also been observed experimentally [34,35].…”

Section: Introductionmentioning

confidence: 92%

Few-boson tunneling dynamics of strongly correlated binary mixtures in a double well

et al. 2012

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We explore the tunneling dynamics of strongly correlated bosonic mixtures in a one-dimensional double well. The roles of the inter-and intraspecies interactions and their interplay are investigated using the numerically exact multiconfiguration time-dependent Hartree (MCTDH) method. The dynamics is studied for three initial configurations: complete and partial population imbalance and a species-separated state. Increasing the interspecies interaction leads to a strong increase of the tunneling time period analogous to the quantum self-trapping for condensates. The intraspecies repulsion can suppress or enhance the tunneling period depending on the strength of the interspecies correlations as well as the initial configuration. Completely correlated tunneling between the two species and within the same species as well as mechanisms of species separation and counterflow are revealed. These effects are explained by studying the few-body energy spectra as well as the properties of the contributing stationary states.

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Quantum dynamics of bosons in a double-well potential: Josephson oscillations, self-trapping and ultralong tunneling times

Cited by 53 publications

References 29 publications

Interspecies tunneling in one-dimensional Bose mixtures

Interspecies tunneling in one-dimensional Bose mixtures

Dynamical effects of exchange symmetry breaking in mixtures of interacting bosons

Few-boson tunneling dynamics of strongly correlated binary mixtures in a double well

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