1.Introduction 2.Absorption and Emission of Light 2.1 Cavity Modes 2.2 Thermal Radiation and Planck's Law 2.3 Absorption, Induced, and Spontaneous Emission 2.4 Basic Photometric Quantities 2.5 Polarization of Light 2.6 Absorption and Emission Spectra 2.7 Transition Probabilities 2.8 Coherence Properties of Radiation Fields 2.9 Coherence of Atomic Systems Problems 3.Widths and Profiles of Spectral Lines 3.1 Natural Linewidth 3.2 Doppler Width 3.3 Collisional Broadening of Spectral Lines 3.4 Transit-Time Broadening 3.5 Homogeneous and Inhomogeneous Line Broadening 3.6 Saturation and Power Broadening 3.7 Spectral Line Profiles in Liquids and Solids Problems 4.Spectroscopic Instrumentation 4.1 Spectrographs and Monochromators 4.2 Interferometers 4.3 Comparison Between Spectrometers and Interferometers 4.4 Accurate Wavelength Measurements 4.5 Detection of Light 4.6 Conclusions Problems 5.Lasers as Spectroscopic Light Sources 5.1 Fundamentals of Lasers 5.2 Laser Resonators 5.3 Spectral Characteristics of Laser Emission 5.4 Experimental Realization of Single-Mode Lasers 5.5 Controlled Wavelength Tuning of Single-Mode Lasers 5.6 Linewidths of Single-Mode Lasers 5.7 Tunable Lasers 5.8 Nonlinear Optical Mixing Techniques 5.9 Gaussian Beams Problems 6.Doppler-Limited Absorption and Fluorescence Spectroscopy with Lasers 6.1 Advantages of Lasers in Spectroscopy 6.2 High-Sensitivity Methods of Absorption Spectroscopy 6.3 Direct Determination of Absorbed Photons 6.4 Ionization Spectroscopy 6.5 Optogalvanic Spectroscopy 6.6 Velocity-Modulation Spectroscopy 6.7 Laser Magnetic Resonance and Stark Spectroscopy 6.8 Laser-Induced Fluorescence 6.9 Comparison Between the Different Methods Problems 7.Nonlinear Spectroscopy 7.1 Linear and Nonlinear Absorption 7.2 Saturation of Inhomogeneous Line Profiles 7.3 Saturation Spectroscopy 7.4 Polarization Spectroscopy 7.5 Multiphoton Spectroscopy 7.6 Special Techniques of Nonlinear Spectroscopy 7.7 Conclusion Problems 8.Laser Raman Spectroscopy 8.1 Basic Considerations 8.2 Experimental Techniques of Linear Laser Saman Spectroscopy 8.3 Nonlinear Raman Spectroscopy 8.4 Special Techniques 8.5 Applications of Laser Raman Spectroscopy Problems 9.Laser Spectroscopy in Molecular Beams 9.1 Reduction of Doppler Width 9.2 Adiabatic Cooling in Supersonic Beams 9.3 Formation and Spectroscopy of Clusters and Van der Waals Molecules in Cold Molecular Beams 9.4 Nonlinear Spectroscopy in Molecular Beams 9.5 Laser Spectroscopy in Fast Ion Beams 9.6 Applications of FIBLAS 9.7 Spectroscopy in Cold Ion Beams 9.8 Combination of Molecular Beam Laser Spectroscopy and Mass Spectrometry Problems 10.Optical Pumping and Double-Resonance Techniques 10.1 Optical Pumping 10.2 Optical-RF Double-Resonance Technique 10.3 Optical-Microwave Double Resonance 10.4 Optical-Optical Double Resonance 10.5 Special Detection Schemes of Double-Resonance Spectroscopy Problems 11.Time-Resolved Laser Spectroscopy 11.1 Generation of Short Laser Pulses 11.2 Measurement of Ultrashort Pulses 11.3 Lifetime Measurement with Lasers 11.4 Pump-and-Probe Technique Problems 12.Coherent Spectroscopy 12.1 Level-Crossing Spectroscopy 12.2 Quantum-Beat Spectroscopy 12.3 Excitation and Detection of Wave Packets in Atoms and Molecules 12.4 Optical Pulse-Train Interference Spectroscopy 12.5 Photon Echoes 12.6 Optical Nutation and Free-Induction Decay 12.7 Heterodyne Spectroscopy 12.8 Correlation Spectroscopy Problems 13.Laser Spectroscopy of Collision Processes 13.1 High-Resolution Laser Spectroscopy of Collisional Line Broadening and Line Shifts 13.2 Measurements of Inelastic Collision Cross Sections of Excited Atoms and Molecules 13.3 Spectroscopic Techniques for Measuring Collision-Induced Transitions in the Electronic Ground State of Molecules 13.4 Spectroscopy of Reactive Collisions 13.5 Spectroscopic Determination of Differential Collision Cross Sections in Crossed Molecular Beams 13.6 Photon-Assisted Collisional Energy Transfer 13.7 Photoassociation Spectroscopy of Colliding Atoms Problems 14.New Developments in Laser Spectroscopy 14.1 Optical Cooling and Trapping of Atoms 14.2 Spectroscopy of Single Ions 14.3 Optical Ramsey-Fringes 14.4 Atom Interferometry 14.5 The One-Atom Maser 14.6 Spectral Resolution Within the Natural Linewidth 14.7 Absolute optical Frequency Measurement and Optical Frequency Standards 14.8 Squeezing 15.Applications of Laser Spectroscopy 15.1 Applications in Chemistry 15.2 Environmental Research with Lasers 15.3 Applications to Technical Problems 15.4 Applications in Biology 15.5 Medical Applications of Laser Spectroscopy 15.6 Concluding Remarks References Subject Index
