Abstract

For a system at a temperature of absolute zero, all thermal fluctuations are frozen out, while quantum fluctuations prevail. These microscopic quantum fluctuations can induce a macroscopic phase transition in the ground state of a many-body system when the relative strength of two competing energy terms is varied across a critical value. Here we observe such a quantum phase transition in a Bose–Einstein condensate with repulsive interactions, held in a three-dimensional optical lattice potential. As the potential depth of the lattice is increased, a transition is observed from a superfluid to a Mott insulator phase. In the superfluid phase, each atom is spread out over the entire lattice, with long-range phase coherence. But in the insulating phase, exact numbers of atoms are localized at individual lattice sites, with no phase coherence across the lattice; this phase is characterized by a gap in the excitation spectrum. We can induce reversible changes between the two ground states of the system.

Keywords

Optical latticeSuperfluidityQuantum phase transitionMott insulatorCondensed matter physicsPhysicsUltracold atomQuantum phasesPhase transitionGround stateLattice (music)QuantumCoherence (philosophical gambling strategy)Quantum fluctuationQuantum mechanics

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Publication Info

Year
2002
Type
article
Volume
415
Issue
6867
Pages
39-44
Citations
5708
Access
Closed

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Cite This

Markus Greiner, Olaf Mandel, Tilman Esslinger et al. (2002). Quantum phase transition from a superfluid to a Mott insulator in a gas of ultracold atoms. Nature , 415 (6867) , 39-44. https://doi.org/10.1038/415039a

Identifiers

DOI
10.1038/415039a
PMID
11780110
arXiv
2506.21303

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Data completeness: 84%