Thermodynamics of Bose-Einstein-condensed clouds using phase-contrast imaging

R Meppelink; R.A. Rozendaal; S.B. Koller; J.M. Vogels; P. van der Straten

doi:10.1103/PhysRevA.81.053632

Thermodynamics of Bose-Einstein-condensed clouds using phase-contrast imaging

R Meppelink, R.A. Rozendaal, S.B. Koller, J.M. Vogels, P. van der Straten

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Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Phase contrast imaging is used to observe Bose-Einstein condensates (BECs) at finite temperature in situ. The imaging technique is used to accurately derive the absolute phase shift of a probe laser beam due to both the condensate and the thermal cloud. The accuracy of the method is enhanced by using the periodicity of the intensity signal as a function of the accumulated phase. The measured density profiles can be described using a two relevant parameter fit, in which only the chemical potential and the temperature are to be determined. This allows us to directly compare the measured density profiles to different mean-field models in which the interaction between the condensed and thermal atoms is taken into account to various degrees

Original language	English
Article number	053632
Number of pages	12
Journal	Physical review. A, Atomic, molecular and optical physics
Volume	81
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevA.81.053632
Publication status	Published - 2010

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Thermodynamics Meppelink 2010
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title = "Thermodynamics of Bose-Einstein-condensed clouds using phase-contrast imaging",

abstract = "Phase contrast imaging is used to observe Bose-Einstein condensates (BECs) at finite temperature in situ. The imaging technique is used to accurately derive the absolute phase shift of a probe laser beam due to both the condensate and the thermal cloud. The accuracy of the method is enhanced by using the periodicity of the intensity signal as a function of the accumulated phase. The measured density profiles can be described using a two relevant parameter fit, in which only the chemical potential and the temperature are to be determined. This allows us to directly compare the measured density profiles to different mean-field models in which the interaction between the condensed and thermal atoms is taken into account to various degrees",

author = "R Meppelink and R.A. Rozendaal and S.B. Koller and J.M. Vogels and {van der Straten}, P.",

year = "2010",

doi = "10.1103/PhysRevA.81.053632",

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AU - Koller, S.B.

AU - Vogels, J.M.

AU - van der Straten, P.

PY - 2010

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N2 - Phase contrast imaging is used to observe Bose-Einstein condensates (BECs) at finite temperature in situ. The imaging technique is used to accurately derive the absolute phase shift of a probe laser beam due to both the condensate and the thermal cloud. The accuracy of the method is enhanced by using the periodicity of the intensity signal as a function of the accumulated phase. The measured density profiles can be described using a two relevant parameter fit, in which only the chemical potential and the temperature are to be determined. This allows us to directly compare the measured density profiles to different mean-field models in which the interaction between the condensed and thermal atoms is taken into account to various degrees

AB - Phase contrast imaging is used to observe Bose-Einstein condensates (BECs) at finite temperature in situ. The imaging technique is used to accurately derive the absolute phase shift of a probe laser beam due to both the condensate and the thermal cloud. The accuracy of the method is enhanced by using the periodicity of the intensity signal as a function of the accumulated phase. The measured density profiles can be described using a two relevant parameter fit, in which only the chemical potential and the temperature are to be determined. This allows us to directly compare the measured density profiles to different mean-field models in which the interaction between the condensed and thermal atoms is taken into account to various degrees

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DO - 10.1103/PhysRevA.81.053632

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JF - Physical review. A, Atomic, molecular and optical physics

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Thermodynamics of Bose-Einstein-condensed clouds using phase-contrast imaging

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