Location via proxy:   [ UP ]  
[Report a bug]   [Manage cookies]                

Effects of classical stochastic webs on the quantum dynamics of cold atomic gases in a moving optical lattice

N. Welch, M. T. Greenaway, and T. M. Fromhold
Phys. Rev. A 96, 053623 – Published 17 November 2017
PDFHTMLExport Citation
Abstract
Authors
Article Text
  • INTRODUCTION
  • SEMICLASSICAL MODELING OF THE PERTURBED…
  • CONCLUSION
  • ACKNOWLEDGMENTS
    • References

    Abstract

    We introduce and investigate a system that uses temporal resonance-induced phase-space pathways to create strong coupling between an atomic Bose-Einstein condensate and a traveling optical lattice potential. We show that these pathways thread both the classical and quantum phase space of the atom cloud, even when the optical lattice potential is arbitrarily weak. The topology of the pathways, which form weblike patterns, can by controlled by changing the amplitude and period of the optical lattice. In turn, this control can be used to increase and limit the BEC's center-of-mass kinetic energy to prespecified values. Surprisingly, the strength of the atom-lattice interaction and resulting BEC heating of the center-of-mass motion is enhanced by the repulsive interatomic interactions.

    • Figure
    • Figure
    • Figure
    • Figure
    • Figure
    • Figure
    • Figure
    • Received 1 August 2017

    DOI:https://doi.org/10.1103/PhysRevA.96.053623

    ©2017 American Physical Society

    Physics Subject Headings (PhySH)

    1. Research Areas
    Atomic & molecular processes in external fieldsCold atoms & matter wavesCold gases in optical lattices
    Atomic, Molecular & Optical

    Authors & Affiliations

    N. Welch1, M. T. Greenaway2, and T. M. Fromhold1

    • 1Midlands Ultracold Atom Research Center, School of Physics & Astronomy, University of Nottingham, Nottingham NG7 2RD, United Kingdom
    • 2Department of Physics, Loughborough University, Loughborough LE11 3TU, United Kingdom

    Article Text (Subscription Required)

    Click to Expand

    References (Subscription Required)

    Click to Expand
    Issue

    Vol. 96, Iss. 5 — November 2017

    Reuse & Permissions
    Access Options
    Author publication services for translation and copyediting assistance advertisement

    Authorization Required

    Log In
    Other Options
    ×

    Images

    • Figure 1
      Figure 1

      Isodensity surface (red) of a BEC that is confined in a 3D harmonic potential and subject to a plane-wave potential [high (low) potential energy shown in green (blue)] traveling along the z direction, corresponding to the lowest frequency of the harmonic trap.

      Reuse & Permissions
    • Figure 2
      Figure 2

      Comparison between the energy per atom, E(t), in the BEC calculated vs time t, shown in units of τz, for resonant and nonresonant plane-wave driving and for different strengths of interatomic interaction: Dark-blue solid (labeled 3) and dashed (labeled 2) curves show R=1 resonant heating for noninteracting (g=0) and interacting atoms, respectively; red (labeled 4) and light-blue (labeled 5) curves show nonresonant heating for R=0.95 and R=2, respectively (g=0 in both cases); green curve (labeled 1) shows R=2 heating for g=0 and Vo=1.3ωz. Vo=0.3ωz for all other curves. In all cases, N=104 and kc=0.5/lx.

      Reuse & Permissions
    • Figure 3
      Figure 3

      (a, i–iv) Position-momentum (z,pz) phase-space Wigner functions (normalized moduli, |W|/N, plotted) showing the time evolution calculated for a noninteracting atom cloud with resonant R=1 plane-wave driving. (i) t=0, cloud at rest; (ii)t=τz, cloud has been excited to a larger phase-space radius, ρ=z2+pz2, along the pz=0 pathway; (iii) t=7τz, cloud reaches, and scatters from, a ring-shaped dynamical barrier; (iv) t=17τz, cloud begins to contract along the pz=0 pathway, reducing its mean ρ value and energy. (b, i–iv) Phase-space evolution calculated for an interacting atom cloud (g=g0) at times (i) t=0, cloud at rest but repulsive interactions produce a larger initial phase-space spread than for g=0; (ii) t=6τz, cloud is excited as in (a,ii) except that the interactions have distorted the phase-space distribution; (iii) t=17τz, the cloud reaches the ring-shaped dynamical barrier and scatters from it, becoming fragmented; (iv) t=25τz, cloud continues to evolve in phase space with no reduction in its energy. Color bar shows normalized values of the Wigner function modulus.

      Reuse & Permissions
    • Figure 4
      Figure 4

      (a) Classical Poincaré section (dots) calculated for an Rb87 atom driven by a plane wave. Blue and red dashed curves show, respectively, the location of the radial and first ring-shaped filaments of the stochastic web that encloses the islands of stability shown in black. (b)–(d) Wigner functions (normalized moduli plotted: color bar lower right) that are periodically time averaged over 40τz for R=1 with (b) g=0 and (c) g=g0, and for R=2 with (d) g=0. For all panels, Vo=0.3ωz. (a)–(c) kc=0.5/lz; (d) kc=0.75/lz.

      Reuse & Permissions
    • Figure 5
      Figure 5

      Maximum energy of atom clouds calculated vs wave vector, kc (shown multiplied by lz), of the plane-wave driving potential. Blue curve shows Ering1 values given by Eq. (5). Black (red) symbols are maximum energies calculated using the GPE with g=g0 (g=0). Insets: Wigner functions (moduli plotted) calculated for R=1 and kc= (a) 0.4/lz, (b) 0.75/lz peak around the classical stochastic webs in phase space.

      Reuse & Permissions
    • Figure 6
      Figure 6

      Color map (scale right) showing the total energy E of each atom in an Rb87 BEC calculated vs time (in units of τz) and the amplitude Vo (in units of ωz) of a plane-wave driving potential with kc=0.5lz. The map is shown both as a surface plot (upper) and a 2D projection (lower). Along the dashed curve in the projection, the BEC's energy is 90% of the energy limit given by Eq. (5).

      Reuse & Permissions
    • Figure 7
      Figure 7

      Atom density profiles calculated for an Rb87 BEC with g=go shown in the x=0 plane for R= (a) 1, (b) 2 at times t= (i) 5.00τz, (ii) 5.25τz, (iii) 5.50τz, (iv) 5.75τz, (v) 6.00τz. (a, i–v) Large-amplitude center-of-mass oscillation during which the BEC maintains a spatially coherent form. (b, i–v) There is no center-of-mass oscillation, but significant deformation and fragmentation of the atom cloud.

      Reuse & Permissions
    ×

    Sign up to receive regular email alerts from Physical Review A

    Log In

    Cancel
    ×

    Search

    Article Lookup

    Paste a citation or DOI
    Enter a citation
    ×