2016
DOI: 10.1088/0953-4075/49/7/075302
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Quasi one-dimensional Bose–Einstein condensate in a gravito-optical surface trap

Abstract: Abstract. We study both static and dynamic properties of a weakly interacting BoseEinstein condensate (BEC) in a quasi one-dimensional gravito-optical surface trap, where the downward pull of gravity is compensated by the exponentially decaying potential of an evanescent wave. First, we work out approximate solutions of the Gross-Pitaevskii equation for both a small number of atoms using a Gaussian ansatz and a larger number of atoms using the Thomas-Fermi limit. Then we confirm the accuracy of these analytica… Show more

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Cited by 8 publications
(14 citation statements)
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“…In the following considerations we assume ω y = 2π × 12.0 kHz , which fulfills the quasi two-dimensional condition ω y >> ω ⊥ for the ESWP experiment. As the BEC does not penetrate very far into the repulsive ESWP, it is hardly influenced by the Van-der-Waals potential, which follows from the above values of the GOST experiment 30 . In order to do the numerical simulation, we use the dimensionless equation as here, we consider dimensional spatial coordinates z = κz and x = κx , the dimensionless time t = t(mg)/ κ and the two-particle dimensionless interaction strength G = N2 √ 2πãk/ã y , here, ã = aκ being a dimensionless s-wave scattering length, ã y = a y κ is the dimensionless oscillator length along the y-axis, and k = 2 κ 3 /(g m 2 ) defines the dimensionless kinetic energy constant.…”
Section: Figure 1 (A)mentioning
confidence: 53%
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“…In the following considerations we assume ω y = 2π × 12.0 kHz , which fulfills the quasi two-dimensional condition ω y >> ω ⊥ for the ESWP experiment. As the BEC does not penetrate very far into the repulsive ESWP, it is hardly influenced by the Van-der-Waals potential, which follows from the above values of the GOST experiment 30 . In order to do the numerical simulation, we use the dimensionless equation as here, we consider dimensional spatial coordinates z = κz and x = κx , the dimensionless time t = t(mg)/ κ and the two-particle dimensionless interaction strength G = N2 √ 2πãk/ã y , here, ã = aκ being a dimensionless s-wave scattering length, ã y = a y κ is the dimensionless oscillator length along the y-axis, and k = 2 κ 3 /(g m 2 ) defines the dimensionless kinetic energy constant.…”
Section: Figure 1 (A)mentioning
confidence: 53%
“…Previously, we have studied the behavior of Cs BEC in a quasi-1D GOST, we developed an analytical approximate solution of GOST and compared with numerical simulations and with Innsbruck experimental data 30 . The analytical solution of this complicated problem is only possible around GOST minimum harmonic potential 30 . However, the system gets quite complected when the anharmonicities started to play the role, therefore, it is not possible to solve this research problem analytically.…”
Section: Retroreflection and Diffraction Of A Bose-einstein Condensatmentioning
confidence: 99%
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“…Figure 2 illustrates the parametric excitation of the two-soliton molecule. Ordinary differential equations (23) and (24) If the coefficient of nonlocal nonlinearity γ(t) = 2d 2 ρ(t) of a system vary periodically with time ρ(t) = 1 + ε sin(ω 0 t + ϕ 0 ), then an equilibrium position can be unstable, even if it stable for each fixed value of the parameter. This instability is what makes it possible for the parametric excitation of the two-siliton molecule to appear.…”
Section: The Variational Approximationmentioning
confidence: 99%
“…Mitschke's group described the first experimental demonstration of the existence of temporal optical soliton molecules. In recent experiment 14 with ultracold polar molecules, full control over the internal states of ultracold 23 Na 87 Rb polar molecules was obtained. The authors used the microwave spectroscopy to control the rotational and hyperfine states of ultracold ground state 23 Na 87 Rb polar molecules, which were created by them.…”
Section: Introductionmentioning
confidence: 99%