Advances in Atomic, Molecular, and Optical Physics (eBook)
498 Seiten
Elsevier Science (Verlag)
978-0-08-055490-7 (ISBN)
.International experts
.Comprehensive articles
.New developments"
Volume 55 of the Advances in Atomic, Molecular, and Optical Physics Series contains seven contributions, covering a diversity of subject areas in atomic, molecular and optical physics. In their contribution, Stowe, Thorpe, Pe'er, Ye, Stalnaker, Gerginov, and Diddams explore recent developments in direct frequency comb spectroscopy. Precise phase coherence among successive ultrashort pulses of a frequency comb allows one to probe fast dynamics in the time domain and high-resolution structural information in the frequency domain for both atoms and molecules. The authors provide a detailed review of some of the current applications that exploit the unique features of frequency comb spectroscopy and discuss its future directions. Yurvsky, Olshanii and Weiss review theory and experiment of elongated atom traps that confine ultracold gases in a quasi-one-dimensional regime. Under certain conditions, these quasi-one-dimensional gases are well-described by integrable one-dimensional many-body models with exact quantum solutions. Thermodynamic and correlation properties of one such model that has been experimentally realized are reviewed. DePaola, Morgenstein and Andersen discuss magneto-optical trap recoil ion momentum spectroscopy (MOTRIMS), exploring collisions between a projectile and target resulting in charged target fragments. MOTRIMS combines the technology of laser cooling and trapping of target atoms with the momentum analysis of the charged fragments that recoil from the target. The authors review the different MOTRIMS experimental approaches and the spectroscopic and collisional investigations performed so far. Safronova and Johnson give an overview of atomic many-body perturbation theory and discuss why extensions of the theory are needed. They present "e;all-order results based on a linearized version of coupled cluster expansions and apply the theory to calculations of energies, transition matrix elements and hyperfine constants. Another contribution on atomic theory, authored by Fischer, explores the advantages of expanding the atomic radial wave functions in a B-spline basis. The differential equations are replaced by non-linear systems of equations and the problems of orthogonality requirements can be dealt with using projection operators. Electron-ion collisional processes are analyzed by Mueller, including descriptions of the experimental techniques needed to obtain cross section data and typical values for these cross sections. The present status of the field is discussed in relation to the detailed cross sections and rate coefficients that are needed for understanding laboratory or astrophysical plasmas. Finally, Duan and Monroe review ways to achieve scalable and robust quantum communication, state engineering, and quantum computation. Using radiation and atoms, ions, or atomic ensembles, they show that they can construct scalable quantum networks that are inherently insensitive to noise. Progress in experimental realization of their proposals is outlined. - International experts- Comprehensive articles- New developments
Cover 1
Contents 6
Contributors 10
Chapter 1. Direct frequency comb spectroscopy 12
1. Introduction and Historical Background 13
2. Comb Control and Detection 16
3. Direct Frequency Comb Spectroscopy 23
4. Multi-Frequency Parallel Spectroscopy 41
5. Coherent Control Applications 49
6. Future Outlook 56
7. Concluding Remarks 63
8. Acknowledgements 63
9. References 64
Chapter 2. Collisions, correlations, and integrability in atom waveguides 72
1. Introduction 73
2. Effective 1D World 75
3. Bethe Ansatz and beyond 96
4. Ground State Properties of Short-Range-Interacting 1D Bosons: Known Results and Their Experimental Verification 114
5. What Is Special about Physics in 1D 124
6. Summary and Outlook 136
7. Acknowledgements 137
8. Appendix: Some Useful Properties of the Hurwitz Zeta Function 137
9. References 138
Chapter 3. MOTRIMS: Magneto-Optical Trap Recoil Ion Momentum Spectroscopy 150
1. Introduction to MOTRIMS 151
2. Relative Total Electron Transfer Cross Sections 158
3. Case Studies in Total Electron Transfer Collisions 160
4. Case Studies of Differential Electron Transfer Cross Sections 172
5. Probing Excitation Dynamics 183
6. Future Applications 191
7. Concluding Comments 195
8. Acknowledgements 196
9. References 196
Chapter 4. All-Order Methods for Relativistic Atomic Structure Calculations 202
1. Introduction and Overview 203
2. Relativistic Many-Body Perturbation Theory 205
3. Relativistic SD All-Order Method 209
4. Motivation for Further Development of the All-Order Method 217
5. Recent Developments in the Calculations of Monovalent Systems: Non-Linear Terms and Triple Excitations 220
6. Many-Particle Systems 224
7. Applications of High-Precision Calculations 230
8. Conclusion 241
9. Acknowledgements 242
10. References 242
Chapter 5. B-splines in variational atomic structure calculations 246
1. Introduction 247
2. The Hartree-Fock Approximation 249
3. Multiconfiguration Hartree-Fock Approximation 260
4. B-Spline Theory 262
5. B-Spline Methods for the Many-Electron Hartree-Fock Problem 272
6. B-Spline MCHF Equations 286
7. Conclusion 299
8. Acknowledgements 300
9. References 300
Chapter 6. Electron-ion collisions: Fundamental processes in the focus of applied research 304
1. Introduction 305
2. Basics of Electron-Ion Collisions 309
3. Experimental Access to Data 330
4. Overview of Experimental Results on Free-Electron-Ion Collisions 366
5. Conclusions 408
6. Acknowledgements 410
7. References 410
Chapter 7. Robust probabilistic quantum information processing with atoms, photons, and atomic ensembles 430
1. Introduction 431
2. Quantum Communication with Atomic Ensembles 432
3. Quantum State Engineering with Realistic Linear Optics 445
4. Quantum Computation through Probabilistic Atom-Photon Operations 453
5. Summary 470
6. Acknowledgements 471
7. References 471
Index 476
Contents of Volumes in this Serial 484
Erscheint lt. Verlag | 9.8.2011 |
---|---|
Sprache | englisch |
Themenwelt | Sachbuch/Ratgeber |
Naturwissenschaften ► Chemie ► Analytische Chemie | |
Naturwissenschaften ► Physik / Astronomie ► Atom- / Kern- / Molekularphysik | |
Naturwissenschaften ► Physik / Astronomie ► Optik | |
Naturwissenschaften ► Physik / Astronomie ► Quantenphysik | |
Technik | |
ISBN-10 | 0-08-055490-3 / 0080554903 |
ISBN-13 | 978-0-08-055490-7 / 9780080554907 |
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