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Anderson localization of weakly interacting bosons
Giovanni Modugno LENS and Dipartimento di Fisica, Università di Firenze 2° INSTANS Conference, September 11, 2008
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The team G. Roati, L. Fallani, G. M., C. D’Errico C. Fort, M. Inguscio, M. Fattori, M. Modugno, M. Zaccanti
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Disorder Disorder is ubiquitous in nature
Superfluids in porous media Superconducting thin films Wave propagation in random media Still under investigation, despite of several decades of research; also applicative interests Wave propagation in engineered materials (photonic lattices)
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Anderson localization
No transport can occurr for D>J, due to the destructive interference of many possible paths
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Anderson localization
An essential feature is the absence of interactions between particles: Light in powders and disordered photonic crystals Van Albada & Lagendijk, Phys. Rev. Lett. 55, 2692 (1985) Wiersma, et al. , Nature 390, 671 (1997) Lahini, et al., Phys. Rev. Lett. 100, (2008). Microwaves Dalichaouch, et al, Nature 354, 53 (1991). Ultrasounds Weaver, Wave Motion 12, (1990). Disordered electronic systems Akkermans & Montambaux Mesoscopic Physics of electrons and photons (Cambridge University Press,2006). Lee & Ramakrishnan, Rev. Mod. Phys. 57, 287 (1985) Dynamical systems (kicked rotor) under study Chabè et al, arXiv:0709:4320.
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What about ultracold atoms?
Both Bose and Fermi gases available in traps Optical standing-waves realize perfect lattices with adjustable dimensionality
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What about ultracold atoms?
The atoms in a Bose-Einstein condensate are naturally interacting Bose glass in a disordered lattice? L. Fallani et al., Phys. Rev. Lett. 98, (2007) Mott insulator in an ordered lattice M. Greiner et al., Nature 415, 39 (2002)
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What about ultracold atoms?
Tuning of the atom-atom interaction (s-wave scattering length) is in some case possible through magnetically-tunable Feshbach resonances Moerdijk et al, Phys. Rev. A 51, 4852 (1995); Inouye et al, Nature 392, 151 (1998).
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Our approach to Anderson localization
A binary incommensurate lattice in 1D: quasi-disorder is easier to realize than random disorder, but shows the same phenomenology An ultracold Bose gas of 39K atoms: precise tuning of the interaction to zero Investigation of transport in space and of momentum distribution: direct observation of Anderson localization for matter-waves
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localization transition at finite D = 2J
Disorder models 1D Anderson model pure random localization for any D 1D Aubry-André model quasiperiodic localization transition at finite D = 2J incommensurate lattice speckle
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Realization of the Aubry-Andrè model
The first lattice sets the tunneling energy J The second lattice controls the site energy distribution D S. Aubry and G. André, Ann. Israel Phys. Soc. 3, 133 (1980); G. Harper, Proc. Phys. Soc. A 68, 674 (1965). Grempel, D. R., Fishman, S. & Prange, R. E., Phys. Rev. Lett. 49, (1982).
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Localization threshold in the A-A model
localized states: extended states: Solution of the A-A model for the experimental parameters: b = 1030/860 =
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Energy spectrum } 4J } 2D Localization takes place at energies well above the disorder
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The weakly interacting Bose gas
G. Roati et al. Phys. Rev. Lett. 99, (2007).
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Experimental scheme Roati et al., Nature 453, 895 (2008)
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Probing the transport properties
The noninteracting BEC is initially confined in a harmonic trap and then left free to expand in the quasiperiodic lattice D/J Ballistic expansion: Ballistic expansion with reduced velocity Absence of diffusion:
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Probing the transport properties
D/J = 0 D/J = 1.8 D/J = 4.2 D/J = 7 0 ms ballistic expansion ballistic expansion at reduced speed time localization 750 ms
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Scaling behavior: onset of localization
Probing the transport properties Size of the condensate after 750 ms of expansion in the quasi-periodic lattice: Scaling behavior: onset of localization only depends on D/J
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Probing the spatial distribution
No disorder: wavefunction is delocalized on the whole system size ... … a harmonic trap is present: gaussian distribution With disorder: eigenstates are exponentially localized
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Exponential localization
gaussian exponential Fit of the density distribution with a generalized exponential function: D/J = 0 D/J = 1.8 D/J = 4.2 D/J = 7
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Probing the momentum distribution
narrow peaks in p(k) broad peaks in p(k) Long free expansion: xk
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Scaling behavior with D/J
Probing the momentum distribution experiment theory Density distribution after time-of-flight of the initial stationary state Scaling behavior with D/J Width of the central peak Visibility
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Counting the localized states
one localized state two localized states three localized states ~10 localized states
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AL of matter-waves in random disorder (no lattice)
Before expansion Semilog plot BEC (t=0) After expansion J. Billy et al., Nature 453, 891 (2008) (Bouyer-Aspect group, Orsay)
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AL of photons in a quasi-disordered lattice
Lahini. et al., arXiv (2008). (Group of Silberberg, Weizmann)
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What’s next? Disorder with controllable interaction. The disordered Bose-Hubbard model: Higher dimensionality for disorder; ideal and superfluid Fermi gases; random disorder; …
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Delocalization due to interaction: preliminary
No interaction: few independent localized states With interaction: localized states get more extendend and lock in phase
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Delocalization due to interaction: preliminary
a=1.7 a0 U=0.15 D a=9.6 a0 U=0.8 D a=23 a0 U=2.0 D
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Quantum gases experiments at LENS
Three-body Efimov physics Quantum gases with dipolar interaction R q E Quantum interferometry, and fundamental forces close to surfaces
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