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Universal Loss Dynamics in a Unitary Bose Gas

Abstract : The low temperature unitary Bose gas is a fundamental paradigm in few-body and many-body physics, attracting wide theoretical and experimental interest. Here we first present a theoretical model that describes the dynamic competition between two-body evaporation and three-body re-combination in a harmonically trapped unitary atomic gas above the condensation temperature. We identify a universal magic trap depth where, within some parameter range, evaporative cooling is balanced by recombination heating and the gas temperature stays constant. Our model is developed for the usual three-dimensional evaporation regime as well as the 2D evaporation case. Experiments performed with unitary 133 Cs and 7 Li atoms fully support our predictions and enable quantitative measurements of the 3-body recombination rate in the low temperature domain. In particular, we measure for the first time the Efimov inelasticity parameter η * = 0.098(7) for the 47.8-G d-wave Feshbach resonance in 133 Cs. Combined 133 Cs and 7 Li experimental data allow investigations of loss dynamics over two orders of magnitude in temperature and four orders of magnitude in three-body loss. We confirm the 1/T 2 temperature universality law up to the constant η *.
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https://hal.inria.fr/hal-01149089
Contributor : Ulrich Eismann <>
Submitted on : Wednesday, May 27, 2015 - 10:34:10 PM
Last modification on : Saturday, May 30, 2020 - 8:18:01 PM
Document(s) archivé(s) le : Monday, April 24, 2017 - 4:44:28 PM

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  • HAL Id : hal-01149089, version 2
  • ARXIV : 1505.04523

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Ulrich Eismann, Lev Khaykovich, Sébastien Laurent, Igor Ferrier-Barbut, Benno S. Rem, et al.. Universal Loss Dynamics in a Unitary Bose Gas. 2015. ⟨hal-01149089v2⟩

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