Laser-induced damage of optical materials

The laser power handling capacities of optical systems are determined by the physical properties of their component materials. At low intensity levels these factors are not important, but an understanding of damage mechanisms is fundamental to good design of laser products operating at high power. Laser Induced Damage of Optical Materials presents a comprehensive overview of the damage processes that occur at high laser intensity levels and explains how these factors limit the energy handling capabilities of optical systems. The first two chapters of the book review basic EM theory, and consider optical effects, including absorption and scattering processes, that occur at low and medium energy levels. Chapter 3 describes the damage mechanisms that come into effect when intensity levels are raised. Chapter 4 discusses the central theory for the definition and measurement of the laser-induced damage thresholds of optical materials. This covers both thermal damage and dielectric breakdown as a function of absorption and laser pulse length and spot size. The following chapters are devoted to surfaces and sub-surface damage, coatings, measurement techniques, and special topics such as scaling and the importance of using the correct measurement unit systems. Laser Induced Damage of Optical Materials is an invaluable resource to those working with optical systems where high laser intensity is a factor.

Glossary of Terms OPTICAL EFFECTS AT LOW POWER/ENERGY LEVELS Introduction Electromagnetic Theory Dispoersion Reflectance and Transmittance Reflectance and Absortance of a Conducting Surface Molecular Polarizability Absorption Scatter Analysis of R, T, A and S Measurements OPTICAL EFFECTS AT MEDIUM POWER/ENERGY LEVELS Introduction Absorption Raman Scattering Brillouin Scattering Harmonic Generation Self-Focusing DAMAGE THEORY Introduction Thermal Mechanisms Dielectric Processes Testing Regimes Time of Damage Damage Morphology SURFACES AND SUB-SURFACES Introduction Surfaces Sub-Surface COATINGS Introduction Coating Technology Measurements and Morphology of Coated Surfaces Coating Design Damage to Dielectric Coatings SPECIAL TOPICS Ambient Atmosphere/Gases Liquids Photodetectors Fibre Optics Scaling Laws Significance of the Units of Measurement MEASUREMENT TECHNIQUES Introduction Measurement of Power, Power Density, Energy, and Energy Density Laser-Induced Damage Threshold Measurement of Optical Characteristics Surface Measurement and Specification Other Measurements APPENDICES References Index