Interface and collective modes of a BEC immersed in a Fermi sea

报告题目：Interface and collective modes of a BEC immersed in a Fermi sea

报告人：黄博 博士

主持人：董光炯 教授

时间：2017-12-15  下午2:30

地点：理科大楼A814

报告人简介：

Career

2015-now    Post-Doc at IQOQI, Innsbruck, Austria

2010-2015   Research assistant at University at Innsbruck and junior scientist at IQOQI, Innsbruck

2010          Teaching assistant at University at Innsbruck

Scientific Education and Thesis

2010-2015    Efimov Physics in an Ultracold Cesium Gas

PhD             Supervisor: Prof. Dr. Rudolf Grimm and Prof. Dr. Francesca Ferlaino

                   University at Innsbruck, Innsbruck, Austria

2008-2009    Linewidth Reduction of a Diode Laser by Optical Feedback

MSc             for Strontium BEC Applications

                    Supervisor: Dr. Florian Schreck and Prof. Rudolf Grimm

                    University at Innsbruck, Innsbruck, Austria

2004-2008     System Timing-Control Program and Atom Chip Design

BSc               for the Experiment of Ultra-Cold Atom BEC

                     Supervisor: Prof. Ru-Quan Wang

                     Institute of Physics, Chinese Academy of Science, Beijing, China

2007              Thermal and density structures of H II galaxies deduced from

                     Undergraduate  spectral synthesis based on Sloan Digital Sky Survey Data Release 5

Research        (supported by Chun - Tsung Endowment)

                     Supervisor: Prof. Xiao-Wei Liu

                     Peking University, Beijing, China

报告内容简介：

The static characters and collective dynamics of a trapped Bose-Einstein condensation (BEC) can change significantly when the BEC is strongly interacting with a degenerate Fermi gas. We realize such a quantum mixture with a ⁴¹K BEC immersed in a large single-component degenerate Fermi gas of ⁶Li, and both elements are trapped in an elongated optical dipole trap while the interspecies contact interaction is manipulated by a magnetic Feshbach resonance between the lowest spin state of both elements near 335.08 G. When the interspecies repulsive interaction increases, the two components start to repel each other, i.e. the BEC density is enhanced while the fermions are depleted at the trap center, and finally become spatially separated when the interaction is sufficiently strong.

To study the mixture, we use three-body recombination as a probe to study the overlap between the two species for various interaction strengths and see a decrease in losses when the interactions become strongly repulsive and compare the loss rate to that of a non-condensed bosonic cloud. In a phase-separated mixture, losses only happen at the interface of the two species and are orders of magnitude weaker than that in a mixed phase of both species. To understand our loss rate results, we calculate the spatial overlap between the two components with a mean-field model. This model fits nicely to our experimental results and reveals effects beyond the local density approximation (LDA). On the other hand, we measure the frequencies of BEC collective oscillations at various interaction strengths and observe a substantial change of the frequency of the radial breathing mode. We try to interpret our observations with the Gross-Pitaevskii equation and the Boltzmann equation.