Université Lille 1 Sciences et Technologies, Lille, France Laboratoire de Physique des Lasers, Atomes et Molécules Équipe Chaos Quantique - PDF

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Université Lille 1 Sciences et Technologies, Lille, France Laboratoire de Physique des Lasers, Atomes et Molécules Équipe Chaos Quantique 16 years of experiments on the atomic kicked rotor! Chaos, disorder

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Université Lille 1 Sciences et Technologies, Lille, France Laboratoire de Physique des Lasers, Atomes et Molécules Équipe Chaos Quantique 16 years of experiments on the atomic kicked rotor! Chaos, disorder in dynamical ultracold atom systems Jean-Claude Garreau Workshop Quantum chaos: fundamentals and applications Luchon-Superbagnères 18 Mars Université Lille 1 Sciences et Technologies, Lille, France Laboratoire de Physique des Lasers, Atomes et Molécules Équipe Chaos Quantique PhLAM LKB LPT Clément Hainaut Jamal Kalloufi Isam Manai Radu Chicireanu J.-F. Clément Pascal Szriftgiser JCG Dominique Delande Nicolas Cherroret Gabriel Lemarié 2 The kicked rotor The kicked rotor: A paradigm of classical and quantum chaos 3 /36 Kicked rotor: Chaotic diffusion in phase space 4 /36 The kicked rotor The atomic kicked rotor: An almost ideal quantum simulator 5 /36 The unfolded kicked rotor Free motion Kick 6 /36 Doing it with cold atoms Optical potential 7 /36 Doing it with cold atoms Acoustooptical modulator Cold-atom cloud Mirror F. L. Moore et al., Atom optics realization of the quantum d-kicked rotator, Phys. Rev. Lett. 75, 4598 (1995) 8 /36 Doing it with cold atoms 9 /36 Quantum-simulating the Anderson model Probing quantum disordered systems with ultracold atoms 10 /36 The Anderson model Tight-binding Anderson Random: P. W. Anderson, Absence of Diffusion in Certain Random Lattices, Phys. Rev. 109, (1958) 11 /36 Simple picture of the Anderson transition Number of visited sites ~ Absence time Hopping time Localization Diffusion (3D) 3D: Quantum phase transition 12 /36 Anderson model The Anderson model 1D : Exponential localization of the eigenfunctions Suppression of the diffusion Insulator 3D «Mobility edge» Metal-insulator transition 13 /36 Quantum simulators Simulating condensed matter systems with ultracold atoms 14 /36 Experiments in condensed-matter and ultracold atoms Condensed matter Decoherence (ill-defined quantum phases) No access to the wave function Electron-electron Coulomb interactions Ultracold atoms Control of decoherence Access to probability distributions (and even the full wavefunction) Control of interactions (Feshbach resonances) 15 /36 Doing with cold atoms Palaiseau Urbana-Champain Florence 1D: J. Billy et al., Direct observation of Anderson localization of matter-waves in a controlled disorder, Nature 453, 891 (2008) 3D : F. Jendrzejewski et al., Threedimensional localization of ultracold atoms in an optical disordered potential, Nature Physics 8, 398 (2012) 3D : S. S. Kondov et al., Three- Dimensional Anderson Localization of Ultracold Fermionic Matter, Science 334, 66 (2011) 3D : G. Semeghini, et al., Measurement of the mobility edge for 3D Anderson localization, arxiv: (2014) 16 /36 Quantum simulators Simulating the Anderson model with the atomic kicked rotor 17 /36 Dynamical localization Exponential localization in momentum space dynamical localization Can be mathematically mapped into a 1D Anderson model which discribes disorder in quantum system. Predicts exponential localization in real space G. Casati et al., Stochastic behavior of a quantum pendulum under periodic perturbation, Lect. Notes Phys. 93, 334 (1979) S. Fishman et al., Chaos, Quantum Recurrences, and Anderson Localization, Phys. Rev. Lett. 49, (1982) 18 /36 Dynamical localization, experiment with the atomic kicked rotor /36 The Anderson transition In 3D the Anderson model predicts a quantum metal-insulator transition How to do it with the atomic kicked rotor? Maps onto a 3D Anderson model!!! G. Casati et al., Anderson Transition in a One-Dimensional System with Three Incommensurate Frequencies, Phys. Rev. Lett. 62, (1989) 20 /36 The Anderson transition Diffusive Metal Insulator Critic Localized J. Chabé et al., Experimental Observation of the Anderson Metal-Insulator Transition with Atomic Matter Waves, Phys. Rev. Lett. 101, (2008) 21 /36 Critical exponent KR, experimental KR, numerical Anderson, numerical K. Slevin and T. Ohtsuki, Critical exponent for the Anderson transition in the three-dimensional orthogonal universality class, New J. Phys 16, (2014) G. Lemarié et al., Universality of the Anderson transition with the quasiperiodic kicked rotor, EPL 87, (2009) 22 /36 Critical wave function 23 /36 Universality 24 /36 Phase diagram M. Lopez et al., Phase diagram of the anisotropic Anderson transition with the atomic kicked rotor: theory and experiment, New J. Phys 15, (2013). 25 /36 2D Anderson localization D =2 is the lower critical dimension for Anderson physics All states are localized but with exponentially large localization length Experiment limited to a few ms 26 /36 Vertical geometry Not a kicked rotor (kicked accelerator) 27 /36 Recent results: 2D Anderson localization (unpublished) I. Manai et al., Experimental observation of two-dimensional Anderson localization with the atomic kicked rotor, to be published 28 /36 Recent results: 2D Anderson localization (unpublished) I. Manai et al., Experimental observation of two-dimensional Anderson localization with the atomic kicked rotor, to be published 29 /36 Recent results: 2D Anderson localization (unpublished) Comparison with the self-consistent prediction I. Manai et al., Experimental observation of two-dimensional Anderson localization with the atomic kicked rotor, to be published 30 /36 Breaking the orthogonal symmetry (brand-new preliminary results!) Experimental Numerical C. Tian et al., Weak Dynamical Localization in Periodically Kicked Cold Atomic Gases, Phys. Rev. Lett. 93, (2004) C. Hainaut et al., to be published 31 /36 Coherent back-scattering (brand-new preliminary results!) Exponential fit of the wings C. Hainaut et al., to be published 32 /36 Coherent back-scattering (brand-new preliminary results!) In the unitary case the CBS peak is there only after two kicks! C. Hainaut et al., to be published 33 /36 Coherent back-scattering (brand-new preliminary results!) C. Hainaut et al., to be published 34 /36 Next Next: Nonlinear interacting systems! 35 /36 The funniest is still to come Use a Bose-Einstein condensate Individual atoms Coherent matter wave Nonlinear quantum disorder! (the ultimate dream or nightmare of a quantum-chaotician?) The K-BEC project: Potassium BEC-nonlinear QKR, started 2014, first results expected 2016 A. S. Pikovsky and D. L. Shepelyansky, Destruction of Anderson Localization by a Weak Nonlinearity, Phys. Rev. Lett. 100, (2008) B. Vermersch and J. C. Garreau, Spectral description of the dynamics of ultracold interacting bosons in disordered lattices, New J. Phys 15, (2013) N. Cherroret et al., How Nonlinear Interactions Challenge the Three-Dimensional Anderson Transition, Phys. Rev. Lett. 112, (2014) L. Ermann and D. L. Shepelyansky, Destruction of Anderson localization by nonlinearity in kicked rotator at different effective dimensions, J. Phys. A: Math. Theor. 47, (2014) 36 /36 Conclusion Ultracold atom physics is very powerful tool for the study of quantum complexity KR as quantum simulator 4D Anderson transition Anderson transition and interactions N. Cherroret et al., Phys. Rev. Lett. 112, (2014) 3D Unitary class (critical exponent) M. Thaha et al., Phys. Rev. E 48, (1993) C. Tian et al., Phys. Rev. Lett. 93, (2004) Harper model and the Hofstadter butterfly R. Lima and D. Shepelyansky, Phys. Rev. Lett. 67, (1991) J. Wang and J. Gong, Phys. Rev. A 77, (R) (2008) Spin-orbit coupled KR: Topological and quantum Hall physics J. P. Dahlhaus et al., Phys. Rev. B 84, (2011) Y. Chen and C. Tian, Phys. Rev. Lett. 113, (2014) 37 /36
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