Instability, dispersion management, and pattern formation in the superfluid flow of a BEC in a cylindrical waveguide

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Instability, dispersion management, and pattern formation in the superfluid flow of a BEC in a cylindrical waveguide Michele Modugno LENS & Dipartimento di Fisica, Università di Firenze, Italy Workshop EHR - Valencia - February 3rd, 2009

BEC v

Summary Optical lattices Instability of the superfluid flow Effect of the radial confinement Managing the dispersion by tuning the lattice velocity Attractive interactions Modulation of the radial confinement Parametric instability and pattern formation Toroidal geometries, quantized circulation

Meanfield regime Gross-Pitaevskii equation: 1D GPE: the radial degrees of freedom are frozen Effective 1D model (NPSE) 3D GPE

Instabilities the stationary solution is energetically stable the system can lower its energy by emitting excitations (dissipative process) small fluctuations do not perturb the evolution small fluctuations grow exponentially in time B. Wu and Q. Niu, New Journal of Physics 5, 104.1 (2003)

Bogoliubov excitations linear regime: Bogoliubov equations: normalization:

Landau (energetic) instability negative eigenvalues instability

Dynamical instability Bogoliubov equations: imaginary frequencies excitations grow exponentially in time

Stability of a Bloch wave p periodic system Bloch waves

Dynamical instability: phonon-antiphonon resonance p/qb=0 p/qb=0.25 p/qb=0.5 phonon dispersion anti-phonons p/qb=0.55 p/qb=0.75 p/qb=1 imaginary component M. Modugno, et al., PRA 70, 043625 (2004) [B. Wu and Q. Niu, PRA 64, 061603(R) (2001); C. Menotti et al., New J. Phys. 5, 112 (2003)]

Stability diagrams for Bloch waves (1D) lattice intensity interactions Landau instability dynamical instability excitation quasimomentum condensate quasimomentum B. Wu and Q. Niu, PRA 64, 061603(R) (2001)

Effect of the radial degrees of freedom axial phonons radial breathing p=0 0<p<1 M. Modugno, C. Tozzo, and F. Dalfovo, PRA 70, 043625 (2004)

3D stability diagrams Same onset for instability from GPE 3D and effective 1D (NPSE)

sound velocity M. Krämer, C. Menotti and M. Modugno, J. of Low Temp. Phys., Vol. 138 (2005)

Dipole mode of a BEC experiment S. Burger et al., PRL 86, 4447 (2001)

Dipole mode of a BEC 3D GPE Linear stability analysis: Exp. critical velocity Center-of-mass velocity vs. time. Center-of-mass velocity vs. BEC quasimomentum in the first Bloch band. M. Modugno, C. Tozzo, and F. Dalfovo, PRA 70, 043625 (2004): simulation of the experiment in S. Burger et al., PRL 86, 4447 (2001)

1D vs 3D 3D: 1D, effective 1D : complete loss of coherence

A BEC in a moving lattice p a lattice with fixed velocity is ramped up adiabatically L. Fallani et al., PRL 93, 140406 (2004)

L. Fallani et al., PRL 93, 140406 (2004)

Dispersion management p control the BEC dispersion by tuning the lattice velocity (for weak nonlinearity)

Dispersion management } m < m m } m < 0 free expansion: m < 0 time reversed evolution P. Massignan and M. Modugno, Phys. Rev. A 67, 023614 (2003)

L. Fallani et al., Phys. Rev. Lett. 91, 240405 (2003) (see also B. Eiermann et al., Phys. Rev. Lett. 91, 060402 (2003))

Attractive interactions G. Barontini and M. Modugno, Phys. Rev. A 76, 041601(R) (2007) Gray area: Landau instability The system is energetically unstable for any velocity no superfluidity according to the Landau criterion. Colored regions: DI (Color scale ~ growth rate of the unstable modes = Im(ωpq)) DI at low p, can be stabilized above a critical threshold (opposite behaviour of that for repulsive BECs) naive explanation: changing the sign of g change of sign of m Weak interactions/shallow lattices: DI takes place via long wavelength (low q) excitations no site-to-site dephasing, collective oscillations Dotted region in (g-i): regimes of DI for the repulsive case Negative m and DI appear in separate regions tune the dispersion relation to negative values avoiding the effects of DI

Waveguide expansion: v=0.2 vb density modulations over several sites of the lattice Axial density plot of the BEC as a function of time during the expansion in the waveguide......and its momentum distribution rapid population of modes at small q ( 0.058qB) (most unstable modes of the uniform system) breathing-like oscillation, no decoherence as observed so far with repulsive BECs oscillation accounted for by the real part of the excitations spectrum + momentum spread due to finite size (fitted frequency = 44.5 Hz real part of frequency of the most unstable modes)

0.5vB < v < vb m < m : enhancement of the expansion near the band edge } attractive interactions are turned into an effective repulsion: boost of the expansion with respect to the free case even when m >m reduced expansion for very large m change of sign of m time-reversed evolution contraction of a BEC initially expanding outwards

Parametric instability & pattern formation L Modulation of the transverse confinement at frequency Ω (GPE + initial quantum/thermal fluctuations) parametric amplification of counter-propagating axial phonons of frequency ω(k) = Ω/2 M. Modugno, C. Tozzo and F. Dalfovo, Phys. Rev. A 74, 061601(R) (2006)

periodic boundary contitions discrete spectrum, k = m2π/l resonance behaviour amplitude of the ±k axial phonons as a function of tmod for Ω=0.6ω (resonance m=8) maximum value of Pk as a function of Ω black squares: 2ω(k) of the Bogoliubov excitations

parametric amplification of phonons spontaneous pattern formation of standing waves with m-periodicity analogous to Faraday s instability M. C. Cross and P. P. Hohenberg, Rev. Mod. Phys. 65, 851 (1993) K. Staliunas et al., Phys. Rev. Lett. 89, 210406 (2002) P. Engels et al., Phys. Rev. Lett. 98, 095301 (2007)

toroidal geometry periodic boundary conditions produced in current experiments S. Gupta et al., Phys. Rev. Lett. 95, 143201 (2005) A. S. Arnold et al., Phys. Rev. A 73, 041606(R) (2006) C. Ryu et al., Phys. Rev. Lett. 99, 260401 (2006) tools for observing fundamental properties: quantized circulation, persistent currents, matter-wave interference, sound waves and solitons in low-d, rotation sensors

Expanded density Density distribution (texp=7 ms) (a) (b) (c) (d) (e) (f) max visibility of the density pattern (20%) max visibility of the velocity pattern 45 μm Azimuthal velocity field Periodic pattern in the velocity field interference fringes of atoms expanding in preferred directions: flower-like structure with m petals in the expanded density profile, reflecting the periodicity of the initial pattern.

quantized circulation The pattern formation is affected by the presence of quantized circulation: if the condensate is initially rotating with angular momentum Lz = κh per particle: in-situ pattern: rotates at the same angular velocity of the condensate expandend pattern: misalignment of opposite petals proportional to κ sensitive detection of quantized circulation