Many-Body Matter-Wave Dark Soliton

We perform a comparative beyond mean-field study of black and grey solitonic excitations in a finite ensemble of ultracold bosons confined to a one-dimensional box. An optimized densityengineering potential is developed and employed together with phase-imprinting to cleanly initialize grey solitons. Based on our recently developed Multi-Layer Multi-Configuration Time-Dependent Hartree Method for Bosons, we demonstrate that quantum fluctuations limit the lifetime of the soliton contrast, which prolongs with increasing soliton velocity. A natural orbital analysis reveals a two-stage process underlying the decay of the soliton contrast. The broken parity symmetry of grey solitons results in a local asymmetry of the orbital mainly responsible for the decay, which leads to a characteristic asymmetry of remarkably localized two-body correlations. The emergence and decay of these correlations as well as their displacement from the instantaneous soliton position are analysed in detail. Finally, the role of phase-imprinting for the many-body dynamics is illuminated and additional non-local correlations in pairs of counter-propagating grey solitons are unravelled.

Section: Introductionmentioning

confidence: 93%

Many-body processes in black and gray matter-wave solitons

Krönke

Schmelcher

2015

“…1(b) and [9]). Observing numerically that |g 2 (0, 0) − 1| ≪ 1, we may now understand these non-local correlations as a generic property of parity-symmetric systems with essentially two oc-cupied NOs: Denoting the position of the soliton moving to the right/left with x R/L , our above results imply Second, in order to realize a situation with significant deviations of g 2 (0, 0) from unity, we additionally imprint a relative phase of π between the two half-spaces at t = 0 [6][7][8][9]. Thereby, a black soliton is initialized at x = 0.…”

Section: E Applicationsmentioning

confidence: 88%

“…e.g. [6][7][8][9]. Due to the increasing population of this orbital, the depth of the characteristic minimum in the reduced one-body density is reduced, i.e.…”

Section: E Applicationsmentioning

confidence: 99%

“…Examples for such phenomena are the Mott-insulating phase, where e.g. an intra-well Tonks-Girardeau transition for a filling factor of two can be understood in the NO framework [4,5], the quantum-fluctuations induced decay of dark solitons [6][7][8][9], where a NO of particular shape is dominantly responsible for the soliton contrast reduction in the reduced one-body density, and fragmented condensates [10][11][12][13], which are defined as many-body states with two or more macroscopically occupied NOs. While there are proposals for the detection of fragmentation and its degree [14,15], the one-body density ρ 1 (r) has, to the best of our knowledge, not yet been unraveled into the * skroenke@physnet.uni-hamburg.de † pschmelc@physnet.uni-hamburg.de contributions |φ i (r)| 2 of the individual NOs by means of a measurement protocol.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Two-body correlations and natural-orbital tomography in ultracold bosonic systems of definite parity

Krönke

Schmelcher

2015

The relationship between natural orbitals, one-body coherences and two-body correlations is explored for bosonic many-body systems of definite parity with two occupied single-particle states. We show that the strength of local two-body correlations at the parity-symmetry center characterizes the number state distribution and controls the structure of non-local two-body correlations. A recipe for the experimental reconstruction of the natural orbital densities and quantum depletion is derived. These insights into the structure of the many-body wave-function are applied to the predicted quantum-fluctuations induced decay of dark solitons.

“…Using time-dependent Bogoliubov theory [18][19][20] as well as more sophisticated numerical techniques [21][22][23][24][25] to treat the many-body dynamics of one-dimensional bosons at zero temperature, it has been shown that beyond-mean-field effects tend to deplete the condensate and to fill the soliton notch making dark solitons unstable. Here, however, we study theoretically the role of many-body correlations in determining relevant properties of gray solitons in a three-dimensional (3D) Bose gas, such as their excitation energy, density profile, and effective mass.…”

Section: Introductionmentioning

confidence: 99%

Variational Monte Carlo study of soliton excitations in hard-sphere Bose gases

Rota

Giorgini

2015

By using a full many-body approach, we calculate the excitation energy, the effective mass, and the density profile of soliton states in a three-dimensional Bose gas of hard spheres at zero temperature. The many-body wave function used to describe the soliton contains a one-body term, derived from the solution of the Gross-Pitaevskii equation, and a two-body Jastrow term, which accounts for the repulsive correlations between atoms. We optimize the parameters in the many-body wave function via a variational Monte Carlo procedure, calculating the grand-canonical energy and the canonical momentum of the system in a moving reference frame where the soliton is stationary. As the density of the gas is increased, significant deviations from the mean-field predictions are found for the excitation energy and the density profile of both dark and gray solitons. In particular, the soliton effective mass m * and the mass m N of missing particles in the region of the density depression are smaller than the result from the Gross-Pitaevskii equation, their ratio, however, being well reproduced by this theory up to large values of the gas parameter. We also calculate the profile of the condensate density around the soliton notch, finding good agreement with the prediction of the local-density approximation.