Physics Department Colloquium
Quantum Phase Transitions and Scale Invariance of Atomic Quantum Gases
Time: 3:30 PM
Place: 2241 Chamberlin Hall (coffee at 430 pm)
Speaker: Cheng Chin, University of Chicago
Abstract: Atoms at ultralow temperatures are fascinating quantum objects, which can tunnel through barriers, repel or attract each other, and interfere like electromagnetic waves. This wavy behavior of ultracold atoms evidently illustrates the particlewave duality as discussed in quantum physics. By loading repulsively interacting atoms into tiny optical cells (or optical lattices), we show that the wavy nature of the atoms can be completely suppressed. At the same time, the gaseous sample develops an interesting multilayer structure with density plateaus, resembling a multitier wedding cake. Our observation of the cake structure in 2D ultracold gases [1] raises new prospects to investigate the dynamics and transport across the phase boundary [2] and to identify universal scaling laws in the (quantum) critical regime [3]. Surprising findings along these directions will be presented and discussed.
References:
[1] In situ Observation of incompressible Mottinsulating domains in atomic gases Nathan Gemelke, Xibo Zhang, ChenLung Hung, Cheng Chin Nature 460, 995 (2009)
[2] Slow Mass Transport and Statistical Evolution of An Atomic Gas Across the SuperfluidMott Insulator Transition ChenLung Hung, Xibo Zhang, Nathan Gemelke, Cheng Chin Phys. Rev. Lett. 104.160403 (2010)
[3] Observation of scale invariance and universality in twodimensional Bose gases ChenLung Hung, Xibo Zhang, Nathan Gemelke, Cheng Chin Nature (2011) doi:10.1038/nature09722
Host: Saffman
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