New Journal of Physics (Jan 2015)

Real-time dynamics and proposal for feasible experiments of lattice gauge–Higgs model simulated by cold atoms

  • Yoshihito Kuno,
  • Kenichi Kasamatsu,
  • Yoshiro Takahashi,
  • Ikuo Ichinose,
  • Tetsuo Matsui

DOI
https://doi.org/10.1088/1367-2630/17/6/063005
Journal volume & issue
Vol. 17, no. 6
p. 063005

Abstract

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Lattice gauge theory has provided a crucial non-perturbative method in studying canonical models in high-energy physics such as quantum chromodynamics. Among other models of lattice gauge theory, the lattice gauge–Higgs model is a quite important one because it describes a wide variety of phenomena/models related to the Anderson–Higgs mechanism, such as superconductivity, the standard model of particle physics, and the inflation process of the early Universe. In this paper, we first show that atomic description of the lattice gauge model allows us to explore real-time dynamics of the gauge variables by using the Gross–Pitaevskii equations. Numerical simulations of the time development of an electric flux reveal some interesting characteristics of the dynamic aspect of the model and determine its phase diagram. Next, to realize a quantum simulator of the U(1) lattice gauge–Higgs model on an optical lattice filled by cold atoms, we propose two feasible methods: (i) Wannier states in the excited bands and (ii) dipolar atoms in a multilayer optical lattice. We pay attention to the constraint of Gauss's law and avoid nonlocal gauge interactions.

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