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Published byWendy Whitehead Modified over 9 years ago
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Non-Equilibrium Dynamics in Ultracold Interacting Atoms Sergio Smith (Howard University) Simulations of Ultracold Atoms in Optical Lattices
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Introduction Ultracold atoms ( <1μK ) Cold enough to be trapped and studied Laser and evaporative cooling Bose-Einstein Condensates (BECs) Magnetic moment Two-level system: spin up and spin down Optical lattice Grid of standing light waves Potential wells at highest intensity locations
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E4E4 E3E3 E2E2 E1E1 Quantum effects 1. Quantized energy levels Lowest energy state 2.Wave-particle duality 3.Tunneling
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The Experiment Two-dimensional lattice Atoms loaded into wells Two sub-lattices Rubidum-87 atoms Cool evaporatively Become BECs Potential lowered to allow tunneling Measured quantity: Staggered Magnetization Distribution of atoms on sub-lattices
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Simulation Wave function Single site ≈ Gaussian Random initial phase Some phase “memory” governed by α. Many-body system Sum of local functions Disregard spatial evolution Discretized Gross-Pitaevskii Equation
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Results J →J+δJ U=0.03J O= Experimental Data Good qualitative agreement Calculated value of J was wrong Possibly due to screening effect α=0.6 α=0.8
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Relevance and Future Research Optical lattice experiments provide a highly tunable environment to study magnetism in BECs, with relevance to high-temperature superconductors. Future research includes: Fine-tuning J and α to fit experimental results Studying what causes these discrepancies
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Acknowledgements Dr. Michael Foss-Feig Staff of Joint Quantum Institute (JQI) and Institute for Research in Electronics and Applied Physics (IRAEP) at the University of Maryland, College park.
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