UID:
almahu_9948026632102882
Format:
1 online resource (225 p.)
Edition:
1st ed.
ISBN:
1-280-59615-5
,
9786613625984
,
0-444-53862-3
Series Statement:
Contemporary concepts of condensed matter science,
Content:
The rapidly developing topic of ultracold atoms has many actual and potential applications for condensed-matter science, and the contributions to this book emphasize these connections. Ultracold Bose and Fermi quantum gases are introduced at a level appropriate for first-year graduate students and non-specialists such as more mature general physicists. The reader will find answers to questions like: how are experiments conducted and how are the results interpreted? What are the advantages and limitations of ultracold atoms in studying many-body physics? How do experiments on ultracol
Note:
Description based upon print version of record.
,
Front Cover; Ultracold Bosonic and Fermionic Gases; Copyright; Table of Contents; List of Contributors; Series Preface; Contemporary Concepts of Condensed Matter Science; Volume Preface; 1 Experimental Methods of Ultracold Atomic Physics; 1. Introduction: Why So Cold?; 2. Manipulation of Atoms and Molecules; 2.1. Atomic Structure Basics; 2.2. Magnetic Trapping; 2.3. Electrostatic and Optical Trapping; 2.4. Optical Lattices; 3. Interactions; 3.1. The Scattering Length; 3.2. Feshbach Resonances; 3.3. Dipolar Interactions; 4. Taking Data
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4.1. The Experimental Cycle: The Birth and Death of an Ultracold Gas4.2. Imaging; 4.3. Bragg and Modulation Spectroscopy; 4.4. Single-Atom Probes; 5. Interpreting Data; 5.1. Extracting Thermodynamic Quantities from Spatial Density Profiles; 5.2. What One Learns About Quantum Gases from Their Decay; 5.3. Isolation versus Equilibrium; 6. Conclusion; Acknowledgments; References; 2 Bose Gas: Theory and Experiment; 1. Introduction to Bose Superfluids: Brief Review of Superfluid 4He; 1.1. Two-Fluid Model; 1.2. Quantized Circulation; 1.3. Quasiparticles and the Landau Critical Velocity
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2. Three-Dimensional Ideal Bose Gas2.1. Qualitative Picture of Bose-Einstein Condensation in a Uniform System; 2.2. Quantitative Description of Iideal Bose Gas in an External Potential Vtr; 2.3. Ideal Bose Gas in Three-Dimensional Box with Periodic Boundary Conditions; 2.4. Ideal Bose Gas in Three-Dimensional Harmonic Trap; 2.5. Ideal Bose Gas in Harmonic Traps with Reduced Dimensions; 3. Energies and Length Scales for Interacting Bose Gas; 3.1. Interaction Energy for a Uniform Gas; 3.2. Healing Length for a Uniform Gas; 4. Gross-Pitaevskii Picture for a Trapped Bose Gas; 4.1. Static Behavior
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4.2. Time-Dependent GP Equation4.3. Bogoliubov Spectrum: Linearized Hydrodynamic Equations for a Uniform Bose Gas; 4.4. Linearized Hydrodynamic Equations for Collective Modes of a Stationary Condensate; 4.5. Effect of Attractive Interactions; 5. Selected Applications and Comparison with Experiments; 5.1. Free Expansion for Different Trap Aspect Ratios; 5.2. Measurement of the Condensate Fraction; 5.3. Low-Lying Collective Oscillation Modes; 6. Dipolar Condensates; 7. Mixtures; 7.1. Interacting Two-Component Mixtures; 7.2. Electromagnetic Coupling Between Two Hyperfine States
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8. Spinor Condensates8.1. Spinor Condensates: Special Case of F=1; 8.2. Experimental Studies of Spinor Condensates; 9. Rotating Bose Gases and Quantized Vortices; 9.1. The Scissors Mode; 9.2. The Nucleation of Vortices; 9.3. The Use of Rotation for Direct Quantum Simulation; 10. Synthetic (Artificial) Gauge Fields-Vortices Without Rotation; Acknowledgments; References; 3 The Fermi Gases and Superfluids: Experiment and Theory; 1. Introduction; 1.1. Theory Summary and Overview; 1.2. Creating Quantum Degenerate Fermi Gases; 1.3. Feshbach Resonances
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2. Establishing Pair Condensation and Superfluidity in Cold Fermi Gases
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English
Additional Edition:
ISBN 0-444-53857-7
Language:
English
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