Kooperativer Bibliotheksverbund

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Format: 1 online resource (497 p.)

ISBN: 1-281-03698-6 , 9786611036980 , 0-08-052768-X

Content: The field of atom interferometry has expanded rapidly in recent years, and todays research laboratories are using atom interferometers both as inertial sensors and for precision measurements. Many researchers also use atom interferometry as a means of researching fundamental questions in quantum mechanics.Atom Interferometry contains contributions from theoretical and experimental physicists at the forefront of this rapidly developing field. Editor Paul R. Berman includes an excellent balance of background material and recent experimental results,providing a general overview of atom

Note: Description based upon print version of record. , Front Cover; Atom Interferometry; Copyright Page; Contents; Contributors; Preface; Chapter 1. Optics and Interferometry with Atoms and Molecules; I. Introduction; II. Beam Machine; III. Optics for Atoms and Molecules; IV. Interferometry with Atoms and Molecules; V. Atom Interferometry Techniques; VI. Measuring Atomic and Molecular Properties; VII. Fundamental Studies; VIII. Inertial Effects; IX. Outlook; Appendix: Frequently Used Symbols; References; Chapter 2. Classical and Quantum Atom Fringes; I. Introduction; II. Experimental Apparatus; III. Classical Atom Fringes: The Moire Experiment , IV. Quantum Fringes: The InterferometerV. Comparing Classical and Quantum Fringes: The Classical Analog to an Interferometer; VI. Atoms in Light Crystals; References; Chapter 3. Generalized Talbot-Lau Atom Interferometry; I. Introduction; II. SBE Interferometry; III. GTL Interferometry vs. SBE Interferometry; IV. What Happens When Frauenhofer Diffraction Orders Overlap?; V. Historical Development of the Generalized Talbot Effect; VI. Spatial Properties of the Generalized Talbot Effect ""Image""; VII. Wavelength Dependence of the Spatial Spectrum of the Fringe Intensity; VIII. The Lau Effect , IX. The Talbot InterferometerX. Generalized Lens-Free Talbot-Lau Interferometers; XI. Fresnel Diffraction and the Talbot Effect with a Spatially Varying Potential; XII. GTL Atom Interferometry Experiments with K and Li2; XIII. Talbot Interferometer Using Na; XIV. ""Heisenberg Microscope"" Decoherence GTL Atom Interferometry; XV. Conclusions and Future Applications; Appendix: Kirchoff Diffraction with Spatially Varying V ( r ); References; Chapter 4. Interferometry with Metastable Rare Gas Atoms; I. Introduction; II. Atomic Beam Source; III. Young's Double-Slit Experiment , IV. Holographic Manipulation of AtomsV. Two-Atom Correlation; References; Chapter 5. Classical and Nonclassical Atom Optics; I. Introduction; II. Models and Notation; III. Atom Focusing and Applications; IV. Correlation Experiments with Atoms and Photons; V. Scheme for an Atomic Boson Laser; References; Chapter 6. Atom Interferometry and the Quantum Theory of Measurement; I. Introduction; II. Fundamental Physics and Atom Interferometers; III. The Stern-Gerlach Interferometer; IV. Conclusion; References; Chapter 7. Matter-Wave Interferometers: A Synthetic Approach , I. Physics of the Generalized Beam SplitterII. Architecture of Interferometers; III. Sensitivity to Gravitational and Electromagnetic Fields: A Unified Approach through the Dirac Equation; IV. Conclusions and Directions of Future Progress; References; Chapter 8. Atom Interferometry Based on Separated Light Fields; I. Introduction; II. Theoretical Framework; III. Discussion of Different Types of Interferometers; IV. Experimental Realization of Borde Interferometry; V. Precision Determination of Physical Quantities; VI. Geometrical and Topological Phases , VII. Influence of the Quantum-Mechanical Measurement Process in the Interferometer , English

Additional Edition: ISBN 0-12-092460-9

Language: English

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Format: XVI, 519 S. : , Ill., graph. Darst.

ISBN: 978-0-691-14056-8

Note: Includes bibliographical references and index

Language: English

Subjects: Physics

Keywords: Laserspektroskopie ; Quantenoptik ; Lehrbuch

URL: http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=020876038&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA

URL: Inhaltsverzeichnis

URL: Inhaltstext

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Format: XVI, 464 S. , graph. Darst.

ISBN: 0120922452

Series Statement: Advances in atomic, molecular, and optical physics : Supplements 2

Language: English

Subjects: Physics

Keywords: Casimir-Effekt ; Quantenfeldtheorie ; Hohlraum ; Quantenelektrodynamik

UID:

Format: XVIII, 478 S. , Ill., graph. Darst.

ISBN: 0120924609

Language: English

Subjects: Physics

Keywords: Atom ; Optische Eigenschaft ; Interferometrie ; Interferometer ; Atom ; Interferometrie ; Aufsatzsammlung ; Aufsatzsammlung

URL: http://www.loc.gov/catdir/description/els032/96009899.html

URL: http://www.loc.gov/catdir/toc/els032/96009899.html

UID:

Format: XVI, 464 S. : graph. Darst.

ISBN: 0-12-092245-2

Series Statement: Advances in atomic, molecular, and optical physics : Supplements 2

Language: English

Subjects: Physics

Keywords: Casimir-Effekt ; Quantenfeldtheorie ; Hohlraum ; Quantenelektrodynamik

URL: Inhaltsverzeichnis

URL: http://www.loc.gov/catdir/description/els032/93007607.html

URL: http://www.loc.gov/catdir/toc/els032/93007607.html

UID:

Format: XVI, 464 S. : graph. Darst.

ISBN: 0-12-092245-2

Series Statement: Advances in atomic, molecular, and optical physics : Supplements 2

In: yr:1994

In: no:2

Language: English

Subjects: Physics

Keywords: Casimir-Effekt ; Quantenfeldtheorie ; Hohlraum ; Quantenelektrodynamik

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Format: 1 Online-Ressource (XVI, 637 p. 101 illus., 82 illus. in color).

ISBN: 978-3-319-68598-4

Series Statement: UNITEXT for Physics

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-3-319-68596-0

Language: English

Subjects: Physics

Keywords: Quantenmechanik

DOI: 10.1007/978-3-319-68598-4

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Format: 1 Online-Ressource (XVI, 637 p. 101 illus., 82 illus. in color).

ISBN: 978-3-319-68598-4

Series Statement: UNITEXT for Physics

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-3-319-68596-0

Language: English

Subjects: Physics

Keywords: Quantenmechanik

DOI: 10.1007/978-3-319-68598-4

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Format: 1 online resource (473 p.)

ISBN: 0-12-800301-4

Content: Advances in Atomic, Molecular, and Optical Physics publishes reviews of recent developments in a field that is in a state of rapid growth, as new experimental and theoretical techniques are used on many old and new problems. Topics covered include related applied areas, such as atmospheric science, astrophysics, surface physics and laser physics. Articles are written by distinguished experts and contain relevant review material and detailed descriptions of important recent developments. International experts Comprehensive articles New developments.

Note: Bibliographic Level Mode of Issuance: Monograph , Front Cover -- Advances in Atomic, Molecular, and Optical Physics -- Copyright -- Contents -- Contributors -- Preface -- Chapter One: Detection of Metastable Atoms and Molecules using Rare Gas Matrices -- 1. Introduction -- 2. Basic Concepts -- 2.1 Relevant Background -- 2.2 Principle of Operation of the Detector -- 3. Experimental Details -- 3.1 TOF Spectroscopy -- 3.2 Apparatus Details -- 3.3 Apparatus Performance -- 3.3.1 Spectral Output -- 3.3.2 Temperature Variation -- 3.3.3 Excimer Lifetimes -- 4. Calibrations -- 4.1 Calibration of O(1S) Production -- 4.2 Calibration of O(1D) Production -- 4.2 Calibration of the Electron Energy Scale -- 5. O(1S) Measurements -- 5.1 O2 -- 5.2 N2O -- 5.3 CO2 -- 5.4 CO -- 5.5 NO -- 5.6 H2O, D2O -- 5.7 SO2 -- 6. O(1D) Measurements -- 7. Sulfur Measurements -- 8. CO Measurements -- 9. Future Possibilities -- References -- Chapter Two: Interactions in Ultracold Rydberg Gases -- 1. Introduction -- 2. Pair Interactions -- 2.1 Rydberg Pair Interaction and Important Issues -- 2.2 Calculation of Rydberg Pair Interactions -- 2.3 Angular Dependence -- 2.4 Experiments -- 3. Rydberg Atom Molecules -- 3.1 Trilobite Molecules -- 3.1.1 The Fermi Pseudo-Potential Picture of Trilobite Molecules -- 3.1.2 The Multichannel Quantum Defect Approach to Trilobite Molecules -- 3.1.3 External Fields -- 3.1.4 Features of the Trilobite Interaction Potentials -- 3.1.5 Molecular Frame Permanent Dipole Moments -- 3.1.6 Experimental Measurement of Trilobite Molecules -- 3.2 Macrodimers -- 3.2.1 Theory of Macrodimers -- 3.2.2 Experimental Detection of Macrodimers -- 4. Many-Body and Multiparticle Effects -- 4.1 Förster Resonance -- 4.2 Dipole Blockade -- 5. Conclusion and Perspectives -- Chapter Three: Atomic, Molecular, and Optical Physics in the Early Universe: From Recombination to Reionization -- 1. Introduction. , 1.1 The Expanding Universe -- 1.2 The Thermal History of the Universe -- 1.3 The Need for Dark Matter -- 1.4 The Role of AMO Physics -- 1.5 Distance Measurements -- 1.6 Acronyms and Variables -- 2. Cosmological Recombination -- 2.1 What Is Cosmological Recombination All About? -- 2.1.1 Initial Conditions and Main Aspect of the Recombination Problem -- 2.1.2 The Three Stages of Recombination -- 2.1.3 What Is So Special About Cosmological Recombination? -- 2.2 Why Should We Bother? -- 2.2.1 Importance of Recombination for the CMB Anisotropies -- 2.2.2 Spectral Distortions from the Recombination Era -- 2.3 Why Do We Need Advanced Atomic Physics? -- 2.4 Simple Model for Hydrogen Recombination -- 2.5 Multilevel Recombination Model and Recfast -- 2.6 Detailed Recombination Physics During Hi Recombination -- 2.6.1 Two-Photon Transitions from Higher Levels -- 2.6.2 The Effect of Raman Scattering -- 2.6.3 Additional Small Corrections and Collision -- 2.7 Detailed Recombination Physics During Hei Recombination -- 2.8 HyRec and CosmoRec -- 3. Pregalactic Gas Chemistry -- 3.1 Fundamentals -- 3.2 Key Reactions -- 3.2.1 Molecular Hydrogen (H2) -- 3.2.2 Deuterated Molecular Hydrogen (HD) -- 3.2.3 Lithium Hydride -- 3.3 Complications -- 3.3.1 Spectral Distortion of the CMB -- 3.3.2 Stimulated Radiative Association -- 3.3.3 Influence of Rotational and Vibrational Excitation -- 4. Population III Star Formation -- 4.1 The Assembly of the First Protogalaxies -- 4.2 Gravitational Collapse and Star Formation -- 4.2.1 The Initial Collapse Phase -- 4.2.2 Three-Body H2 Formation -- 4.2.3 Transition to the Optically Thick Regime -- 4.2.4 Cooling at Very High Densities -- 4.2.5 Influence of Other Coolants -- 4.3 Evolution After the Formation of the First Protostar -- 5. The 21-cm Line of Atomic Hydrogen -- 5.1 Physics of the 21-cm Line -- 5.1.1 Basic 21-cm Physics. , 5.1.2 Collisional Coupling -- 5.1.3 Wouthuysen-Field Effect (Photon Coupling) -- 5.2 Global 21-cm Signature -- 5.2.1 Cosmic Dark Ages and Exotic Heating (zbold0mu mumu dotted40) -- 5.2.2 Lyman-α Coupling (zα z z ) -- 5.2.3 Gas Heating (zh z zα) -- 5.2.4 Growth of H II Regions (zr z zh) -- 5.2.5 Astrophysical Sources and Histories -- 5.3 21-cm Tomography -- 5.3.1 Fluctuations in the Spin Temperature -- 5.3.2 Gas Temperature -- 5.3.3 Ionization Fluctuations -- 5.3.4 Density and Minihalos -- 5.3.5 Redshift Space Distortions -- 6. The Reionization of Intergalactic Hydrogen -- 6.1 Sources of Reionization: Stars -- 6.2 Sources of Reionization: Quasars -- 6.2.1 Secondary Ionizations -- 6.3 The Growth of Ionized Bubbles -- 6.3.1 Photoionization Rates and Recombinations -- 6.3.2 Line Cooling -- 6.4 Reionization as a Global Process -- 7. Summary -- Appendix A. Acronyms -- Appendix B. Symbols -- Chapter Four: Atomic Data Needs for Understanding X-ray Astrophysical Plasmas -- 1. Introduction -- 2. Charge State Distribution -- 2.1 Ionization Processes -- 2.1.1 Collisional Ionization -- 2.1.2 Photoionization -- 2.1.3 Auger Ionization -- 2.2 Recombination -- 2.2.1 Dielectronic Recombination -- 2.2.2 Radiative Recombination -- 2.3 Charge Exchange -- 2.4 Future Needs -- 3. Spectral Features -- 3.1 Energy Levels and Wavelengths -- 3.2 Collisional Excitation Rates -- 3.2.1 H-Like Ions -- 3.2.2 He-Like Ions -- 3.2.3 Neon-Like Ions -- 3.2.4 Other Ions -- 3.3 Radiative Transition Rates (Bound-Bound) -- 3.4 Photoionization/Absorption (Bound-Free) Rates -- 3.5 Fluorescent Innershell Transitions -- 3.6 Charge Exchange Rates -- 3.6.1 Atoms and Ions -- 3.6.2 Molecules and Grains -- 4. Conclusions -- Chapter Five: Energy Levels of Light Atoms in Strong Magnetic Fields -- 1. Introduction -- 2. Historical Background -- 3. The Lightest ``Light'' Atom-Hydrogen. , 4. Light Atoms: Two and Few-Electron Systems -- 5. Concluding Remarks and Future Prospects -- Chapter Six: Quantum Electrodynamics of Two-Level Atoms in 1D Configurations -- 1. Introduction -- 2. The 1D Kernel and Its Spectral Decomposition -- 2.1 Form of the Lienard-Wiechert Kernel in 1D (Friedberg and Manassah, 2008c) -- 2. 2 Initial Time CDR and CLS of a Slab (Friedberg et al., 1973) -- 2.3 Eigenfunctions and Eigenvalues of a Slab (Friedberg and Manassah, 2008c,d,e) -- 2.3.1 Functional Form of the Eigenfunctions -- 2.3.2 Pseudo-Orthogonality Relations -- 2.3.2.1 Odd Eigenfunctions -- 2.3.2.1 Even Eigenfunctions -- 2.3.3 Parseval´s Identity -- 2.4 Differential Form of the Field Equation (Friedberg and Manassah, 2008c) -- 2.5 Inverted System in the Superradiant Linear Regime (Friedberg and Manassah, 2008e) -- 2.6 Comments on the Numerical Results of Superradiance from a Slab -- 3. Propagation of an Ultrashort Pulse in a Slab and the Ensuing Emitted Radiation Spectrum -- 3.1 Time Development and Spectrum of the Radiation Emitted -- 3.1.1 Spectral Analysis (Friedberg and Manassah, 2008d, 2009b) -- 3.1.2 Computation of the Electric Field at the End Planes -- 3.2 The SVEA Closed-Form Expressions (Manassah, 2012a) -- 3.3 The Modified SVEA Closed-Form Expressions (Manassah, 2012b) -- 3.4 Self-Energy of an Initially Detuned Phased State (Friedberg and Manassah, 2010a) -- 3.5 Spectral Distribution of an Initially Detuned Spatial Distribution -- 4. Near-Threshold Behavior for the Pumped Stationary State -- 4.1 Coupled Maxwell-Bloch Equations -- 4.2 Single-Frequency Lasing -- 4.2.1 Single-Frequency Bare Mode -- 4.2.2 Single-Frequency Dressed Mode -- 4.3 Two-Frequency Bare Modes -- 4.4 General Comments -- 5. Polariton-Plasmon Coupling, Transmission Peaks, and Purcell-Dicke Ultraradiance -- 5.1 The Total Transfer Matrix -- 5.2 The Mittag-Leffler Expansion. , 5.3 Interacting Polariton-Plasmon Modes -- 6. Periodic Structures -- 6.1 Density-Modulated Slab (Manassah, 2012e) -- 6.1.1 The Self-Energy at Initial Time -- 6.1.2 Simple Mathematical Analysis for the Giant Shifts -- 6.2 Periodic Multislabs Eigenvalues (Friedberg and Manassah, 2008f) -- 6.2.1 Eigenvalue Condition -- 6.2.2 Precocious Superradiance -- 6.2.3 Eigenvalues at the Bragg Condition as a Function of the Number of Cells -- 7. Conclusion -- Acknowledgments -- Appendix. Transfer Matrix Formalism -- Some Useful Relations of the Pauli Matrices -- Example of an Application of Above Formalism -- References -- Index -- Contents of volumes in this serial. , English

Additional Edition: ISBN 0-12-800129-1

Additional Edition: ISBN 1-322-07614-6

Language: English

UID:

Format: 1 online resource (xiv, 406 pages) : , illustrations (some color).

ISBN: 0-12-408110-X

Series Statement: Advances in atomic, molecular, and optical physics ; volume sixty two

Content: Advances in Atomic, Molecular, and Optical Physics publishes reviews of recent developments in a field that is in a state of rapid growth, as new experimental and theoretical techniques are used on many old and new problems. Topics covered include related applied areas, such as atmospheric science, astrophysics, surface physics and laser physics. Articles are written by distinguished experts and contain relevant review material and detailed descriptions of important recent developments. International experts Comprehensive articles New developments

Note: "ISSN: 1049-250X." , Half Title; Editors; Title Page; Copyright; Contents; Contributors; Preface; 1 Ultracold Few-Body Systems; 1 Introduction; 2 Interactions in Ultracold Gases; 2.1 External Field Control of Interatomic Interactions; 2.2 Interaction Models; 2.2.1 The Zero-Range Model; 2.2.2 Single and Multichannel Models; 3 Efimov Physics in Ultracold Quantum Gases; 3.1 Methods to Explore Three-Body Systems; 3.1.1 Hyperspherical Coordinates; 3.1.2 Other Methods for Solving the Few-Body Schrödinger Equation; 3.1.3 Analytically Extracting Ultracold Inelastic Rates; 3.2 The Efimov Effect vs Efimov Physics , 3.2.1 Conditions for the Efimov Effect3.2.2 Ultracold Three-Body Scattering Rates; 3.3 Experimental Observations in Ultracold Gases; 4 Beyond the Efimov Scenario; 4.1 Efimov Effect at Finite Scattering Energies; 4.1.1 Energy-Dependent Efimov Features When a〉0; 4.1.2 Energy-Dependent Efimov Features When a〈0; 4.1.3 Observing Finite Energy Efimov Features via BEC Collisions; 4.2 Finite-Range Effects; 4.3 Efimov Physics for Narrow Feshbach Resonances; 4.3.1 Three Identical Bosons BBB; 4.3.2 Two-Component Fermion Systems FFF'; 4.4 Efimov Physics Beyond Three-Body Systems , 4.4.1 Universal Four-Body States for Identical Bosons4.4.2 Four-Body Efimov Physics for BBBL Systems; 4.4.3 Four-Body ``Efimov Effect'' in FFFL Systems; 4.4.4 Not Too Few, But Not So Many; 4.5 Forms of Interactions Beyond Efimov; 4.5.1 Three-Body States with -1/r Two-Body Interactions; 4.5.2 Three-Body States with -1/r2 Two-Body Interactions; 5 Other Three-Body Systems Relevant for Cold Atom Physics; 5.1 Three Helium Atoms; 5.2 Three-Body Systems with Alkali-Metal and Helium or Hydrogen Atoms; 6 Outlook; Acknowledgments; References; 2 Shortcuts to Adiabaticity; 1 Introduction , 2 General Formalisms2.1 Invariant-Based Inverse Engineering; 2.2 Counterdiabatic or Transitionless Tracking Approach; 2.3 Fast-Forward Approach; 2.4 Alternative Shortcuts Through Unitary Transformations; 2.5 Optimal Control Theory; 3 Expansions of Trapped Particles; 3.1 Transient Energy Excitation; 3.2 Three-Dimensional Effects; 3.3 Bose-Einstein Condensates; 3.4 Strongly Correlated Gases; 3.5 Experimental Realization; 3.6 Optimal Control; 3.7 Other Applications; 4 Transport; 4.1 Invariant-Based Shortcuts for Transport; 4.2 Transport of a Bose-Einstein Condensate; 5 Internal State Engineering , 5.1 Population Inversion in Two-Level Systems5.2 Effect of Noise and Perturbations; 5.3 Three-Level Systems; 5.4 Spintronics; 5.5 Experiments; 6 Wavepacket Splitting; 7 Discussion; Acknowledgments; References; 3 Excitons and Cavity Polaritons for Optical Lattice Ultracold Atoms; 1 Introduction; 2 Ultracold Atoms in an Optical Lattice as Artificial Crystals; 2.1 Superfluid to Mott-Insulator Transitions; 2.2 Mott Insulator for a Two-Component Bose-Hubbard Model; 3 Excitons in Optical Lattices; 3.1 Resonance Dipole-Dipole Interactions; 3.2 One-Dimensional Atomic Chains , 3.3 Two-Dimensional Planar Optical Lattices , English

Additional Edition: ISBN 0-12-408090-1

Additional Edition: ISBN 1-299-75485-6

Language: English