Atomic and Molecular Spectroscopy [E-Book] : Basic Aspects and Practical Applications / by Sune Svanberg.
Atomic and Molecular Spectroscopy is a wide-ranging review of modern spectroscopic techniques such as X-ray, photoelectron, optical and laser spectroscopy, as well as radiofrequency and microwave techniques. On the fundamental side, it focuses on physical principles and the impact of spectroscopy on...
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Full text |
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Personal Name(s): | Svanberg, Sune, author |
Edition: |
Third, Revised and Enlarged Edition. |
Imprint: |
Berlin, Heidelberg :
Springer,
2001
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Physical Description: |
XV, 586 p. online resource. |
Note: |
englisch |
ISBN: |
9783642981074 |
DOI: |
10.1007/978-3-642-98107-4 |
Series Title: |
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Springer Series on Atomic, Optical, and Plasma Physics ;
6 |
Subject (LOC): |
- 1.Introduction
- 2. Atomic Structure
- 2.1 One-Electron Systems
- 2.2 Alkali Atoms
- 2.3 Magnetic Effects
- 2.4 General Many-Electron Systems
- 2.5 The Influence of External Fields
- 2.6 Hyperfine Structure
- 2.7 The Influence of External Fields (hfs)
- 2.8 Isotopic Shifts
- 3. Molecular Structure
- 3.1 Electronic Levels
- 3.2 Rotational Energy
- 3.3 Vibrational Energy
- 3.4 Polyatomic Molecules
- 3.5 Clusters
- 3.6 Other Molecular Structures
- 4. Radiation and Scattering Processes
- 4.1 Resonance Radiation
- 4.2 Spectra Generated by Dipole Transitions
- 4.3 Rayleigh and Raman Scattering
- 4.4 Raman Spectra
- 4.5 Mie Scattering
- 4.6 Atmospheric Scattering Phenomena
- 4.7 Comparison Between Different Radiation and Scattering Processes
- 4.8 Collision-Induced Processes
- 5. Spectroscopy of Inner Electrons
- 5.1 X-Ray Spectroscopy
- 5.2 Photoelectron Spectroscopy
- 5.3 Auger Electron Spectroscopy
- 6. Optical Spectroscopy
- 6.1 Light Sources
- 6.2 Spectral Resolution Instruments
- 6.3 Detectors
- 6.4 Optical Components and Materials
- 6.5 Optical Methods of Chemical Analysis
- 6.6 Optical Remote Sensing
- 6.7 Astrophysical Spectroscopy
- 7. Radio-Frequency Spectroscopy
- 7.1 Resonance Methods
- 7.2 Microwave Radiometry
- 7.3 Radio Astronomy
- 8. Lasers
- 8.1 Basic Principles
- 8.2 Coherence
- 8.3 Resonators and Mode Structure
- 8.4 Fixed-Frequency Lasers
- 8.5 Tunable Lasers
- 8.6 Nonlinear Optical Phenomena
- 8.7 Ultra-short and Ultra-high-Power Laser Pulse Generation
- 9. Laser Spectroscopy
- 9.1 Basic Principles
- 9.2 Doppler-Limited Techniques
- 9.3 Optical Double-Resonance and Level-Crossing Experiments with Laser Excitation
- 9.4 Time-Resolved Atomic and Molecular Spectroscopy
- 9.5 Ultrafast Spectroscopy
- 9.6 High-Power Laser Experiments
- 9.7 High-Resolution Laser Spectroscopy
- 9.8 Cooling and Trapping of Ions and Atoms
- 10. Laser-Spectroscopic Applications
- 10.1 Diagnostics of Combustion Processes
- 10.2 Laser Remote Sensing of the Atmosphere
- 10.3 Laser-Induced Fluorescence and Raman Spectroscopy in Liquids and Solids
- 10.4 Laser-Induced Chemical Processes
- 10.5 Spectroscopic Aspects of Lasers in Medicine
- Questions and Exercises
- References.