Direct observation of growth and collapse of a Bose-Einstein condensate with attractive interactions

Quantum theory predicts that Bose-Einstein condensation of a spatially homogeneous gas with attractive interactions is precluded by a conventional phase transition into either a liquid or solid. When confined to a trap, however, such a condensate can form, provided that its occupation number does no...

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Bibliographic Details
Published in:Nature (London) 2000-12, Vol.408 (6813), p.692-695
Main Authors: Hulet, Randall G, Gerton, Jordan M, Strekalov, Dmitry, Prodan, Ionut
Format: Article
Language:English
Subjects:
Atoms & subatomic particles
Classical and quantum physics: mechanics and fields
Collapse
Exact sciences and technology
Gases
Humanities and Social Sciences
letter
Matter waves
multidisciplinary
Phase coherent atomic ensembles
quantum condensation phenomena
Physics
Quantum theory
Science
Science (multidisciplinary)
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Summary:Quantum theory predicts that Bose-Einstein condensation of a spatially homogeneous gas with attractive interactions is precluded by a conventional phase transition into either a liquid or solid. When confined to a trap, however, such a condensate can form, provided that its occupation number does not exceed a limiting value. The stability limit is determined by a balance between the self-attractive forces and a repulsion that arises from position-momentum uncertainty under conditions of spatial confinement. Near the stability limit, self-attraction can overwhelm the repulsion, causing the condensate to collapse. Growth of the condensate is therefore punctuated by intermittent collapses that are triggered by either macroscopic quantum tunnelling or thermal fluctuation. Previous observations of growth and collapse dynamics have been hampered by the stochastic nature of these mechanisms. Here we report direct observations of the growth and subsequent collapse of a 7Li condensate with attractive interactions, using phase-contrast imaging. The success of the measurement lies in our ability to reduce the stochasticity in the dynamics by controlling the initial number of condensate atoms using a two-photon transition to a diatomic molecular state.
ISSN:0028-0836
1476-4687
DOI:10.1038/35047030