Modulation of breathers in cigar-shaped Bose–Einstein condensates

Cardoso, Wesley B.; Avelar, A. T.; Bazeia, D.

doi:10.1016/j.physleta.2010.04.050

Cited by 45 publications

(22 citation statements)

References 67 publications

(75 reference statements)

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“…This subject has been greatly upheld by the use of the Feshbachresonance (FR) technique, i.e., the control of the strength of the inter-atomic interactions by externally applied fields [23][24][25], which opens the possibility to implement sophisticated nonlinear patterns. In particular, the management of localized solutions of the Gross-Pitaevskii equation (GPE) [26] by means of the spatially inhomogeneous nonlinearity, which may be created by external nonuniform fields that induce the corresponding FR landscape, has attracted a great deal of interest in theoretical studies [27][28][29][30][31][32][33][34][35][36].In this vein, the existence of bright solitons in systems with purely repulsive, alias self-defocusing (SDF) nonlinearity, in the absence of external linear potentials, was recently predicted [37]. This result is intriguing because the existence of such solutions, supported by SDF-only nonlinearities, without the help of a linear potential, was commonly considered impossible.…”

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confidence: 99%

Bright solitons from the nonpolynomial Schrödinger equation with inhomogeneous defocusing nonlinearities

et al. 2013

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Extending the recent work on models with spatially nonuniform nonlinearities, we study bright solitons generated by the nonpolynomial self-defocusing (SDF) nonlinearity in the framework of the one-dimensional (1D) Muñoz-Mateo -Delgado (MM-D) equation (the 1D reduction of the Gross-Pitaevskii equation with the SDF nonlinearity), with the local strength of the nonlinearity growing at |x| → ∞ faster than |x|. We produce numerical solutions and analytical ones, obtained by means of the Thomas-Fermi approximation (TFA), for nodeless ground states, and for excited modes with 1, 2, 3, and 4 nodes, in two versions of the model, with steep (exponential) and mild (algebraic) nonlinear-modulation profiles. In both cases, the ground states and the single-node ones are completely stable, while the stability of the higher-order modes depends on their norm (in the case of the algebraic modulation, they are fully unstable). Unstable states spontaneously evolve into their stable lower-order counterparts. [22], etc. This subject has been greatly upheld by the use of the Feshbachresonance (FR) technique, i.e., the control of the strength of the inter-atomic interactions by externally applied fields [23][24][25], which opens the possibility to implement sophisticated nonlinear patterns. In particular, the management of localized solutions of the Gross-Pitaevskii equation (GPE) [26] by means of the spatially inhomogeneous nonlinearity, which may be created by external nonuniform fields that induce the corresponding FR landscape, has attracted a great deal of interest in theoretical studies [27][28][29][30][31][32][33][34][35][36].In this vein, the existence of bright solitons in systems with purely repulsive, alias self-defocusing (SDF) nonlinearity, in the absence of external linear potentials, was recently predicted [37]. This result is intriguing because the existence of such solutions, supported by SDF-only nonlinearities, without the help of a linear potential, was commonly considered impossible. In the setting introduced in Ref.[37], the system is described by a nonlinear Schrödinger (NLS) equation with the SDF cubic term, whose strength increases in space rapidly enough towards the periphery. The discovery of bright solitons in this setting has ushered studies of solitary modes in other models with spatially growing repulsive nonlinearities, both local [38][39][40][41][42][43] and nonlocal [44]. More specifically, in Ref. [38] it was demonstrated that spatially inhomogeneous

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confidence: 99%

Bright solitons from the nonpolynomial Schrödinger equation with inhomogeneous defocusing nonlinearities

et al. 2013

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“…In this way, we extend our recent work [11] to the more realistic 3D case. To this end, we use an Ansatz that changes the 3D GP equation into specific 1D equation with constant coefficients, which is easier to solve.…”

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confidence: 73%

“…The presence of nonuniform and time-dependent parameters opens interesting perspectives not only from the theoretical point of view, for investigation of nonautonomous nonlinear equations, but also from the experimental point of view, for the study of the physical properties of the systems. In this context, in a recent work we have considered modulation of genuine breather solutions in cigar-shaped Bose-Einstein condensates (BECs) with potential and nonlinearity depending on both space and time, in the one-dimensional (1D) case [11].The study of BECs of dilute gases of weakly interacting bosons, realized for the first time in 1995 on vapors of rubidium [12] and sodium [13], constitutes a very interesting scenario to modulate breathers, since they are well described by a threedimensional (3D) Gross-Pitaevskii (GP) equation arising from a mean-field dynamics [14]. In the BEC context, one finds high experimental flexibility to control nonlinearity via Feshbach resonance, and confinement profile via optical lattices and harmonic and dipole traps [15], and there we can also investigate the effects of dimensionality reduction on the soliton solution.…”

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Modulation of breathers in the three-dimensional nonlinear Gross-Pitaevskii equation

Avelar

Bazeia²,

Cardoso³

2010

Phys. Rev. E

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In this paper we present analytical breather solutions of the three-dimensional nonlinear generalized GrossPitaevskii equation. We use an Ansatz to reduce the three-dimensional equation with space-and time-dependent coefficients into an one-dimensional equation with constant coefficients. The key point is to show that both the space-and time-dependent coefficients of the nonlinear equation can contribute to modulate the breather excitations. We briefly discuss the experimental feasibility of the results in Bose-Einstein condensates. [8,9], and semiconductor quantum wells [10], the breather excitations play an important role, directly affecting the electronic, magnetic, optical, vibrational and transport properties of the systems.In the above mentioned studies, one usually considers genuine breathers, i.e., solutions which oscillate in time when the nonlinear equation presents constant coefficients (i.e., without modulation). However, in a more realistic scenario the several parameters that characterize the physical systems may depend on both space and time, leading to breather solutions that can be modulated in space and time. The presence of nonuniform and time-dependent parameters opens interesting perspectives not only from the theoretical point of view, for investigation of nonautonomous nonlinear equations, but also from the experimental point of view, for the study of the physical properties of the systems. In this context, in a recent work we have considered modulation of genuine breather solutions in cigar-shaped Bose-Einstein condensates (BECs) with potential and nonlinearity depending on both space and time, in the one-dimensional (1D) case [11].The study of BECs of dilute gases of weakly interacting bosons, realized for the first time in 1995 on vapors of rubidium [12] and sodium [13], constitutes a very interesting scenario to modulate breathers, since they are well described by a threedimensional (3D) Gross-Pitaevskii (GP) equation arising from a mean-field dynamics [14]. In the BEC context, one finds high experimental flexibility to control nonlinearity via Feshbach resonance, and confinement profile via optical lattices and harmonic and dipole traps [15], and there we can also investigate the effects of dimensionality reduction on the soliton solution.In the case of a strong trapping in two spatial directions, the 3D GP equation reduces to the simpler one-dimensional (1D) form, giving rise to the so-called cigar-shaped configuration. The 1D GP equation is a nonlinear Schrödinger equation, which can also be used to investigate pulse propagation in bulk crystals or optical fibers [16]. In a former work, however, the search for analytical solutions of the 1D GP equation with stationary inhomogeneous coefficients has been implemented via similarity transformation [17]. More recently, however, the case of space-and time-dependent coefficients were considered for the cubic [18], the cubic-quintic [19], the quintic [20], and also the GP equation in higher dimensions [21].The similarity transformation wa...

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“…The parameters a 0 , b 0 , c 0 and d 0 facilitate control over nonlinearity. Introducing a self-similar transformation, the solution assumes the form [23][24][25][26][27][28] …”

Section: Theoretical Model and Rogue Wave Solutionmentioning

confidence: 99%

Airy–Bessel modulated self-similar rogue waves in a nonlinear Schrödinger equation model

Kaur

Goyal³

et al. 2014

Journal of Modern Optics

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We construct explicit rogue wave solutions of the generalized nonlinear Schrödinger equation under Airy and Besselmodulated nonlinearity and an external potential, by employing a multivariate self-similarity transformation. A set of conditions in the form of analytical relations among dispersion, external potential and nonlinearity have been found for rogue wave generation. Different dimensions of controllability of the rogue waves are also being explored by varying parameters associated with the nonlinearity coefficients by judiciously choosing the form of the parametric functions.

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Modulation of breathers in cigar-shaped Bose–Einstein condensates

Cited by 45 publications

References 67 publications

Bright solitons from the nonpolynomial Schrödinger equation with inhomogeneous defocusing nonlinearities

Bright solitons from the nonpolynomial Schrödinger equation with inhomogeneous defocusing nonlinearities

Modulation of breathers in the three-dimensional nonlinear Gross-Pitaevskii equation

Airy–Bessel modulated self-similar rogue waves in a nonlinear Schrödinger equation model

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