Self-trapped dynamics in 2D optical lattice

Shuming Li; Rafael Hipolito; Jean-Felix Riou; David Weiss; Anatoli Polkovnikov; Ana Maria Rey

Self-trapped dynamics in 2D optical lattice

POSTER

Abstract

We will discuss a mean field model to study the expansion of an array of one dimensional vertical tubes of cold bosonic atoms confined in a two dimensional optical lattice after the crossed dipole trap used for the initial loading is suddenly turned off. The method uses a Lagrangian formalism to derive Newtonian-like equations of motion that include tunneling between wells and nonlinear mean field effects due to atomic interactions. In our model, the pure mean field dynamics predicts macroscopic self-trapping manifested in accumulation of atoms at the edge of the cloud and formation of a hole at the center. When quantum fluctuations are counted for, the self-trapping is considerably suppressed, and the predictions of the model are in better agreement with the recent experiment measurements.

Authors

Shuming Li

Department of Physics, University of Colorado at Boulder
Rafael Hipolito

Department of Physics, Boston University
Jean-Felix Riou

Physics Department, The Pennsylvania State University, University Park
David Weiss

Physics Department, The Pennsylvania State University, University Park
Anatoli Polkovnikov

Department of Physics, Boston University, Boston University
Ana Maria Rey

JILA, National Institute of Standards and Technology and University of Colorado, Boulder, CO 80309-0440, USA, Department of Physics, University of Colorado (JILA), JILA and Department of Physics, University of Colorado, Boulder, CO 80309, USA, JILA \& Department of Physics, University of Colorado at Boulder, JILA and Department of Physics, University of Colorado, Boulder, Colorado, JILA and University of Colorado, Boulder, CO 80309, USA