| Preface |
| Introduction |
| Energy Transfer Between Radiation and Atomic Transitions / 1: |
| Optical Amplification / 1.1: |
| Interaction of Radiation with Matter / 1.2: |
| Blackbody Radiation / 1.2.1: |
| Boltzmann's Statistics / 1.2.2: |
| Einstein's Coefficients / 1.2.3: |
| Phase Coherence of Stimulated Emission / 1.2.4: |
| Absorption and Optical Gain / 1.3: |
| Atomic Lineshapes / 1.3.1: |
| Absorption by Stimulated Transitions / 1.3.2: |
| Population Inversion / 1.3.3: |
| Creation of a Population Inversion / 1.4: |
| The Three-Level System / 1.4.1: |
| The Four-Level System / 1.4.2: |
| The Metastable Level / 1.4.3: |
| Laser Rate Equations / 1.5: |
| Comparison of Three- and Four-Level Lasers / 1.5.1: |
| Properties of Solid-State Laser Materials / 2: |
| Overview / 2.1: |
| Host Materials / 2.1.1: |
| Active Ions / 2.1.2: |
| Ruby / 2.2: |
| Nd:Lasers / 2.3: |
| Nd:YAG / 2.3.1: |
| Nd:Glass / 2.3.2: |
| Nd:Cr:GSGG / 2.3.3: |
| Nd:YLF / 2.3.4: |
| Nd:YVO[subscript 4] / 2.3.5: |
| Er:Lasers / 2.4: |
| Er:YAG / 2.4.1: |
| Er:Glass / 2.4.2: |
| Tunable Lasers / 2.5: |
| Alexandrite Laser / 2.5.1: |
| Ti:Sapphire / 2.5.2: |
| Cr:LiSAF / 2.5.3: |
| Tm:YAG / 2.5.4: |
| Yb:YAG / 2.6: |
| Laser Oscillator / 3: |
| Operation at Threshold / 3.1: |
| Gain Saturation / 3.2: |
| Circulating Power / 3.3: |
| Oscillator Performance Model / 3.4: |
| Conversion of Input to Output Energy / 3.4.1: |
| Laser Output / 3.4.2: |
| Relaxation Oscillations / 3.5: |
| Theory / 3.5.1: |
| Spike Suppression / 3.5.2: |
| Gain Switching / 3.5.3: |
| Examples of Laser Oscillators / 3.6: |
| Lamp-Pumped cw Nd:YAG Laser / 3.6.1: |
| Diode Side-Pumped Nd:YAG Laser / 3.6.2: |
| End-Pumped Systems / 3.6.3: |
| Ring Laser / 3.7: |
| Laser Amplifier / 4: |
| Single- and Multiple-Pass Pulse Amplifiers / 4.1: |
| Pulse Amplification / 4.1.1: |
| Nd:YAG Amplifiers / 4.1.2: |
| Nd:Glass Amplifiers / 4.1.3: |
| Multipass Amplifier Configurations / 4.1.4: |
| Regenerative Amplifiers / 4.2: |
| cw Amplifiers / 4.3: |
| Signal Distortions / 4.4: |
| Spatial Distortions / 4.4.1: |
| Temporal Distortions / 4.4.2: |
| Depopulation Losses / 4.5: |
| Amplified Spontaneous Emission / 4.5.1: |
| Prelasing and Parasitic Modes / 4.5.2: |
| Reduction of Depopulation Losses / 4.5.3: |
| Self-Focusing / 4.6: |
| Whole-Beam Self-Focusing / 4.6.1: |
| Examples of Self-focusing in Nd:YAG Lasers / 4.6.2: |
| Small-Scale Self-Focusing / 4.6.3: |
| Suppression of Self-Focusing / 4.6.4: |
| Optical Resonator / 5: |
| Transverse Modes / 5.1: |
| Intensity Distribution / 5.1.1: |
| Characteristics of a Gaussian Beam / 5.1.2: |
| Resonator Configurations / 5.1.3: |
| Stability of Laser Resonators / 5.1.4: |
| Diffraction Losses / 5.1.5: |
| Higher-Order Modes / 5.1.6: |
| Mode Selection / 5.1.7: |
| Active Resonator / 5.1.8: |
| Examples of Resonator Designs / 5.1.9: |
| Resonator Modeling and Software Packages / 5.1.10: |
| Longitudinal Modes / 5.2: |
| The Fabry-Perot Interferometer / 5.2.1: |
| Laser Resonator with Gain Medium / 5.2.2: |
| Longitudinal Mode Control / 5.2.3: |
| Injection Seeding / 5.2.4: |
| Intensity and Frequency Control / 5.3: |
| Amplitude Fluctuations / 5.3.1: |
| Frequency Tuning / 5.3.2: |
| Frequency Locking / 5.3.3: |
| Hardware Design / 5.4: |
| Unstable Resonators / 5.5: |
| Confocal Positive-Branch Unstable Resonator / 5.5.1: |
| Negative-Branch Unstable Resonator / 5.5.2: |
| Variable Reflectivity Output Couplers / 5.5.3: |
| Gain, Mode Size, and Alignment Sensitivity / 5.5.4: |
| Wavelength Selection / 5.6: |
| Optical Pump Systems / 6: |
| Pump Sources / 6.1: |
| Flashlamps / 6.1.1: |
| Continuous Arc Lamps / 6.1.2: |
| Laser Diodes / 6.1.3: |
| Pump Radiation Transfer Methods / 6.2: |
| Side-Pumping with Lamps / 6.2.1: |
| Side-Pumping with Diodes / 6.2.2: |
| End-Pumped Lasers / 6.2.3: |
| Face-Pumped Disks / 6.2.4: |
| Thermo-Optic Effects / 7: |
| Cylindrical Geometry / 7.1: |
| Temperature Distribution / 7.1.1: |
| Thermal Stresses / 7.1.2: |
| Photoelastic Effects / 7.1.3: |
| Thermal Lensing / 7.1.4: |
| Stress Birefringence / 7.1.5: |
| Compensation of Optical Distortions / 7.1.6: |
| Slab and Disk Geometries / 7.2: |
| Rectangular-Slab Laser / 7.2.1: |
| Slab Laser with Zigzag Optical Path / 7.2.2: |
| Disk Amplifiers and Lasers / 7.2.3: |
| End-Pumped Configurations / 7.3: |
| Thermal Gradients and Stress / 7.3.1: |
| Thermal Fracture Limit / 7.3.2: |
| Thermal Management / 7.4: |
| Liquid Cooling / 7.4.1: |
| Conduction Cooling / 7.4.2: |
| Air/Gas Cooling / 7.4.3: |
| Q-Switching / 8: |
| Q-Switch Theory / 8.1: |
| Fast Q-Switch / 8.1.1: |
| Slow Q-Switching / 8.1.2: |
| Continuously Pumped, Repetitively Q-Switched Systems / 8.1.3: |
| Mechanical Q-Switches / 8.2: |
| Electro-Optical Q-Switches / 8.3: |
| KDP and KD*P Pockels Cells / 8.3.1: |
| LiNbO[subscript 3] Pockels Cells / 8.3.2: |
| Prelasing and Postlasing / 8.3.3: |
| Depolarization Losses / 8.3.4: |
| Drivers for Electro-Optic Q-Switches / 8.3.5: |
| Acousto-Optic Q-Switches / 8.4: |
| Bragg Reflection / 8.4.1: |
| Device Characteristics / 8.4.2: |
| Passive Q-Switches / 8.5: |
| Cavity Dumping / 8.6: |
| Mode Locking / 9: |
| Pulse Formation / 9.1: |
| Passive Mode Locking / 9.2: |
| Liquid Dye Saturable Absorber / 9.2.1: |
| Coupled-Cavity Mode Locking / 9.2.2: |
| Kerr Lens Mode Locking / 9.2.3: |
| Semiconductor Saturable Absorber Mirror (SESAM) / 9.2.4: |
| Active Mode Locking / 9.3: |
| cw Mode Locking / 9.3.1: |
| Transient Active Mode Locking / 9.3.2: |
| Picosecond Lasers / 9.4: |
| AM Mode Locking / 9.4.1: |
| FM Mode Locking / 9.4.2: |
| Femtosecond Lasers / 9.5: |
| Laser Materials / 9.5.1: |
| Dispersion Compensation / 9.5.2: |
| Examples of Kerr Lens or SESAM Mode-Locked Femtosecond Lasers / 9.5.3: |
| Chirped Pulse Amplifiers / 9.5.4: |
| Nonlinear Devices / 10: |
| Nonlinear Optical Effects / 10.1: |
| Second-Order Nonlinearities / 10.1.1: |
| Third-Order Nonlinearities / 10.1.2: |
| Harmonic Generation / 10.2: |
| Basic Theory of Second Harmonic Generation / 10.2.1: |
| Phase Matching / 10.2.2: |
| Properties of Nonlinear Crystals / 10.2.3: |
| Intracavity Frequency Doubling / 10.2.4: |
| Third Harmonic Generation / 10.2.5: |
| Examples of Harmonic Generation / 10.2.6: |
| Optical Parametric Oscillators / 10.3: |
| Performance Modeling / 10.3.1: |
| Crystals / 10.3.2: |
| Quasi Phase Matching / 10.3.3: |
| Design and Performance / 10.3.4: |
| Raman Laser / 10.4: |
| Device Implementation / 10.4.1: |
| Optical Phase Conjugation / 10.5: |
| Basic Considerations / 10.5.1: |
| Material Properties / 10.5.2: |
| Focusing Geometry / 10.5.3: |
| Pump-Beam Properties / 10.5.4: |
| System Design / 10.5.5: |
| Damage of Optical Elements / 11: |
| Surface Damage / 11.1: |
| Inclusion Damage / 11.2: |
| Damage Threshold of Optical Materials / 11.3: |
| Scaling Laws / 11.3.1: |
| Laser Host Materials / 11.3.2: |
| Optical Glass / 11.3.3: |
| Nonlinear Crystals / 11.3.4: |
| Dielectric Thin Films / 11.3.5: |
| System Design Considerations / 11.4: |
| Choice of Materials / 11.4.1: |
| Design of System / 11.4.2: |
| System Operation / 11.4.3: |
| Laser Safety / Appendix A: |
| Conversion Factors and Constants / Appendix B: |
| Definition of Symbols / Appendix C: |
| References |
| Subject Index |
| Preface |
| Introduction |
| Energy Transfer Between Radiation and Atomic Transitions / 1: |
| Optical Amplification / 1.1: |
| Interaction of Radiation with Matter / 1.2: |
| Blackbody Radiation / 1.2.1: |
