Quantum gases in optical lattices : the atomic Mott insulator
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Publication date
2004-09-13
Authors
Oosten, D. van
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DOI
Document Type
Dissertation
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Abstract
An optical lattice is a periodic potential for atoms, created using
a standing wave pattern of light. Due to the interaction between
the light and the atoms, the atoms are attracted to either the nodes
or the anti-nodes of the standing wave, depending on the exact wave
lenght of the light. This means that if such a lattice is loaded with
a sufficiently high number of ultracold atoms, a periodic array of
atoms is obtained, we an interatomic distance of a few tenths of a
micrometer. In order to obtain such a high number of cold atoms, one
first has to create a so-called Bose-Einstein condensate.
When an optical lattice is loaded from a Bose-Einstein condensate,
it is possible to create a system in which every atom is in the
lowest band of the lattice and there is on average one atom in each
lattice site. Because the lattice potential is created with laser
light, the depth of the lattice can easily be tuned by changing the
intensity of the laser. When the intensity of the laser light is low,
the atoms can tunnel from one site to the next. Due to this tunneling,
the gas of atoms in the lattice will remain superfluid. However, if
the intensity of the laser light is increased to above a certain
critical value, a quantum phase transition occurs to a so-called Mott
insulator.
In this state, the atoms can no longer tunnel due to the fact that
the on-site interaction between atoms becomes more important then
the tunneling probability.
In this PhD thesis, a description is given of the experimental setup
that is being constructed in our group to create these systems in our
lab. Also, a theoretical description is given of these systems and
several important quantities our derived, such as the gap of the
Mott-insulating state. Furthermore, an experiment is proposed that can
be used to accurately measure this gap.
Keywords
atomic physics, laser cooling, Bose-Einstein condensation, quantum phase transitions