Numerically exact quantum dynamics of bosons with time-dependent interactions of harmonic type

Lode, Axel U. J.; Sakmann, Kaspar; Alon, Ofir E.; Cederbaum, Lorenz S.; Streltsov, Alexej I.

doi:10.1103/physreva.86.063606

Cited by 114 publications

(180 citation statements)

References 46 publications

(98 reference statements)

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“…The MCTDHB method has been shown to produce accurate many-body solutions in various applications [19,[40][41][42][43][44], and is well documented in the literature [45,46]. Until recently, MCTDHB has been applied to one-dimensional systems.…”

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confidence: 99%

Breaking the resilience of a two-dimensional Bose-Einstein condensate to fragmentation

et al. 2014

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A two-dimensional Bose-Einstein condensate (BEC) split by a radial potential barrier is investigated. We determine on an accurate many-body level the system's ground-state phase diagram as well as a time-dependent phase diagram of the splitting process. Whereas the ground state is condensed for a wide range of parameters, the time-dependent splitting process leads to substantial fragmentation. We demonstrate for the first time the dynamical fragmentation of a BEC despite its ground state being condensed. The results are analyzed by a mean-field model and suggest that a large manifold of low-lying fragmented excited states can significantly impact the dynamics of trapped two-dimensional BECs. [4][5][6]. While three-dimensional trapped BECs have been extensively studied since their discovery, the static and time-dependent properties of their two-dimensional counterparts are comparatively less explored.One of the most popular scenarios studied with ultracold bosonic atoms, both experimentally and theoretically, is the splitting of a BEC by a central barrier into two spatially-disjoint clouds, e.g., Refs. [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21]. It is a common practice that in order to produce a fragmented BEC in the splitting process, the ground state must be fragmented. This renders high barriers and strong interaction strengths necessary. Previous works dealt with splitting of a BEC in one or three spatial dimensions. To the best of our knowledge, splitting of a BEC in two spatial dimensions has not been explored experimentally or theoretically on the many-body level.In the present work we investigate theoretically, on an accurate many-body level, the physics of splitting a twodimensional (2D) BEC. A natural approach is to exploit the 2D symmetry of the system. We thus split a circular BEC by a radial potential barrier, see Fig. 1a for an illustration. This would lead to two concentric clouds, unlike the above-discussed common way of splitting a BEC and, as we shall see below, enrich the physics of BEC splitting.By analyzing the many-body time-independent and time-dependent wavefunctions of the system, we construct both static and dynamic phase diagrams of the splitting process. Whereas the ground state is condensed for a wide range of parameters, the time-dependent splitting process leads to substantial fragmentation. We therefore demonstrate the dynamical fragmentation of a BEC, despite its ground state being fully condensed. The results imply that a large manifold of fragmented excited states can significantly impact the dynamics of 2D BECs.We consider a repulsive BEC with N = 100 bosons in the 2D circular trap shown in Fig. 1a. Throughout this work dimensionless units are used, such that the single-particle kinetic-energy operator readsT (r) = − 1 2 ∇ 2 r [22]. The explicit form of the one-body potential is given by V (r) = V trap (r) + V barrier (r). Here V trap (r) = {200e −(r−rc) 4 /2 , r ≤ r c = 9; 200, r > r c } is a flat trap which has the shape of "a crater" and V barrier (r) = 200e ...

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Breaking the resilience of a two-dimensional Bose-Einstein condensate to fragmentation

et al. 2014

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“…The N +M −1 N linear equations of motion for the coefficients are coupled to the M non-linear integrodifferential equations of motion of the orbitals. Since the derivation is variational and the basis used is a formally complete set in the limit M → ∞, convergence with respect to the number of orbitals implies the convergence to the exact solution of TDSE for the problem under consideration [41]. The use of time-adaptive orbitals is of key importance for the achievement of numerical exactness: a much smaller number of time-adaptive orbitals is needed to achieve the same level of accuracy as compared to the number of basis functions in a static, time-independent basis [41].…”

Section: Brief Summary and Outlookmentioning

confidence: 99%

“…The key to MCTDHB's efficiency in solving Eq. (1) exactly numerically [41] lies in the usage of a time-dependent, variationally optimized many-body basis set. The introduction of the method and computational details are deferred to Appendix A for brevity.…”

Section: A the Hamiltonianmentioning

confidence: 99%

“…[41]. The method relies on expanding the wavefunction with multiple, time-dependent configurations | n; t weighted with time-dependent coefficients C n (t): |Ψ = n C n (t)| n; t .…”

Section: Brief Summary and Outlookmentioning

confidence: 99%

“…[30] used a novel quantum many-boson method, the multiconfigurational time-dependent Hartree method for bosons (MCTDHB) [37,40]. MCTDHB provides the means to solve the time-dependent many-boson Schrödinger equation numerically exact for a wide range of problems, see, e.g., [30,[41][42][43][44].…”

Section: Introductionmentioning

confidence: 99%

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Controlling the velocities and the number of emitted particles in the tunneling to open space dynamics

et al. 2014

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is put forward and proven to apply for systems with a non-zero threshold value. It is demonstrated that the model is applicable for general interparticle interaction strengths, particle numbers and threshold values. The model constructs the many-body process from single-particle emission processes. The rates and emission momenta of the single-particle processes are determined by the chemical potentials and energy differences to the threshold value of the potential for systems with different particle numbers. The chemical potentials and these energy differences depend on the interparticle interaction. Both the number of confined particles and their rate of emission thus allow for a control by the manipulation of the interparticle interaction and the threshold. Numerically exact results for two, three and one hundred bosons are shown and discussed. The devised control scheme for the many-body tunneling process performs very well for the dynamics of the momentum density, the correlations, the coherence and of the final state, i.e., the number of particles that remain confined in the potential.

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Exploring Many-Body Physics with Bose-Einstein Condensates

Alon

Bagnato

Beinke

et al. 2019

High Performance Computing in Science and Engineering ' 18

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Numerically exact quantum dynamics of bosons with time-dependent interactions of harmonic type

Cited by 114 publications

References 46 publications

Breaking the resilience of a two-dimensional Bose-Einstein condensate to fragmentation

Breaking the resilience of a two-dimensional Bose-Einstein condensate to fragmentation

Controlling the velocities and the number of emitted particles in the tunneling to open space dynamics

Exploring Many-Body Physics with Bose-Einstein Condensates

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