2003
DOI: 10.1103/physrevlett.90.220401
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Soliton-Sound Interactions in Quasi-One-Dimensional Bose-Einstein Condensates

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Cited by 84 publications
(158 citation statements)
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“…The case of manipulation of dark solitons by periodic potentials is more subtle because dark solitons subject to tight confinements are prone to weak radiation loss, as shown numerically in Refs. [454][455][456][457] and analytically in Ref. [263].…”
Section: Periodic Potentialsmentioning
confidence: 99%
“…The case of manipulation of dark solitons by periodic potentials is more subtle because dark solitons subject to tight confinements are prone to weak radiation loss, as shown numerically in Refs. [454][455][456][457] and analytically in Ref. [263].…”
Section: Periodic Potentialsmentioning
confidence: 99%
“…These small-amplitude oscillations last up to t ≈ 770; after that, the soliton has gained the kinetic energy necessary to escape from the well and move to a neighboring one. There, it is again trapped due to a reabsorption of the radiation waves: this effect [14] causes the soliton to become deeper, which results in loss of its kinetic energy, and a subsequent stabilization of its motion. The soliton oscillates in that well from t = 825 up to t = 980.…”
Section: Intermediate Optical Lattice Periodmentioning
confidence: 99%
“…Note that, at t = 1000, the soliton is still oscillating in the potential well of the OL where it was initially placed. For even larger times (not shown here), it is natural to expect that it will escape from the well and will further increase (decrease) the amplitude (frequency) of the oscillation (see also a discussion in the next sections, as well as [14,24] for a detailed description of the effect of radiation). (8), respectively.…”
Section: The Long-period Optical Latticementioning
confidence: 99%
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