M. Aizenman, E. H. Lieb, R. Seiringer, J. P. Solovej, J. Yngvason
Published 2004-12-01Version 1
One of the most remarkable recent developments in the study of ultracold Bose gases is the observation of a reversible transition from a Bose Einstein condensate to a state composed of localized atoms as the strength of a periodic, optical trapping potential is varied. In \cite{ALSSY} a model of this phenomenon has been analyzed rigorously. The gas is a hard core lattice gas and the optical lattice is modeled by a periodic potential of strength $\lambda$. For small $\lambda$ and temperature Bose-Einstein condensation (BEC) is proved to occur, while at large $\lambda$ BEC disappears, even in the ground state, which is a Mott-insulator state with a characteristic gap. The inter-particle interaction is essential for this effect. This contribution gives a pedagogical survey of these results.
Comments: To appear in the proceedings of QMath9, Giens, France, Sept. 12--16, 2004
Journal: in: `Mathematical Physics of Quantum Mechanics, Selected and Refereed Lectures from QMath9', A. Joyce and and J. Ash (eds), Springer Lecture Notes in Physics, vol. 690 (2006)
Rectifying fluctuations in an optical lattice
Critical Behaviour of Structure Factors at a Quantum Phase Transition
Quantum phase transition in space in a ferromagnetic spin-1 Bose-Einstein condensate
