236 research outputs found
Thermally induced coherence in a Mott insulator of bosonic atoms
Conventional wisdom is that increasing temperature causes quantum coherence
to decrease. Using finite temperature perturbation theory and exact
calculations for the strongly correlated bosonic Mott insulating state we show
a practical counter-example that can be explored in optical lattice
experiments: the short-range coherence of the Mott insulating phase can
increase substantially with increasing temperature. We demonstrate that this
phenomenon originates from thermally produced defects that can tunnel with
ease. Since the near zero temperature coherence properties have been measured
with high precision we expect these results to be verifiable in current
experiments.Comment: 5 pages, 3 figure
The Projected Gross-Pitaevskii Equation for harmonically confined Bose gases
We extend the Projected Gross Pitaevskii equation formalism of Davis et al.
[Phys. Rev. Lett. \bf{87}, 160402 (2001)] to the experimentally relevant case
of harmonic potentials. We outline a robust and accurate numerical scheme that
can efficiently simulate this system. We apply this method to investigate the
equilibrium properties of a harmonically trapped three-dimensional Bose gas at
finite temperature, and consider the dependence of condensate fraction,
position and momentum distributions, and density fluctuations on temperature.
We apply the scheme to simulate an evaporative cooling process in which the
preferential removal of high energy particles leads to the growth of a
Bose-Einstein condensate. We show that a condensate fraction can be inferred
during the dynamics even in this non-equilibrium situation.Comment: 11 pages, 7 figure
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