Theory of vortex-lattice melting in a one-dimensional optical lattice
Publication date
2006
Authors
Snoek, M.
Stoof, H.T.C.
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DOI
Document Type
Preprint
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Abstract
We investigate quantum and temperature fluctuations of a vortex lattice in a one-dimensional
optical lattice. We discuss in particular the Bloch bands of the Tkachenko modes and calculate the
correlation function of the vortex positions along the direction of the optical lattice. Because of
the small number of particles in the pancake Bose-Einstein condensates at every site of the optical
lattice, finite-size effects become very important. Moreover, the fluctuations in the vortex positions
are inhomogeneous due to the inhomogeneous density. As a result, the melting of the lattice occurs
from the outside inwards. However, tunneling between neighboring pancakes substantially reduces
the inhomogeneity as well as the size of the fluctuations. On the other hand, nonzero temperatures
increase the size of the fluctuations dramatically. We calculate the crossover temperature from
quantum melting to classical melting. We also investigate melting in the presence of a quartic
radial potential, where a liquid can form in the center instead of at the outer edge of the pancake
Bose-Einstein condensates.