The definition of optical material has expanded in recent years, largely because of IT advances that have led to rapid growth in optoelectronics applications. Helping to explain this evolution, Optical Materials and Applications presents contributions from leading experts who explore the basic concepts of optical materials and the many typical applications in which they are used. An invaluable reference for readers ranging from professionals to technical managers to graduate engineering students, this book covers everything from traditional principles to more cutting-edge topics. It also details recent developmental trends, with a focus on basic optical properties of material. Key topics include: Fundamental optical properties of solids Fundamental optical materials (including thin films) from both linear and nonlinear perspectives Use of bulk materials in the design of various modifications Application of optical thin films in artificial components Formation of artificial structures with sub-wavelength dimensions Use of physical or chemical techniques to control lightwave phase One-, two-, and three-dimensional structures used to control dispersion of materials for nanophotonics Progress of the optical waveguide, which makes optical systems more compact and highly efficient This book carefully balances coverage of theory and application of typical optical materials for ultraviolet, visible and infrared, non-linear optics, solid state lasers, optical waveguides, optical thin films and nanophotonics. It addresses both basic ideas and more advanced topics, making it an equally invaluable resource for beginners and active researchers in this growing field.

The definition of optical material has expanded in recent years, largely because of IT advances that have led to rapid growth in optoelectronics applications. Helping to explain this evolution, Optical Materials and Applications presents contributions from leading experts who explore the basic concepts of optical materials and the many typical applications in which they are used. An invaluable reference for readers ranging from professionals to technical managers to graduate engineering students, this book covers everything from traditional principles to more cutting-edge topics. It also details recent developmental trends, with a focus on basic optical properties of material. Key topics include: Fundamental optical properties of solids Fundamental optical materials (including thin films) from both linear and nonlinear perspectives Use of bulk materials in the design of various modifications Application of optical thin films in artificial components Formation of artificial structures with sub-wavelength dimensions Use of physical or chemical techniques to control lightwave phase One-, two-, and three-dimensional structures used to control dispersion of materials for nanophotonics Progress of the optical waveguide, which makes optical systems more compact and highly efficient This book carefully balances coverage of theory and application of typical optical materials for ultraviolet, visible and infrared, non-linear optics, solid state lasers, optical waveguides, optical thin films and nanophotonics. It addresses both basic ideas and more advanced topics, making it an equally invaluable resource for beginners and active researchers in this growing field.

Research and applications in optical engineering require careful selection of materials. With such a large and varied array to choose from, it is important to understand a material's physical and optical properties before making a selection. Providing a convenient, concise, and logically organized collection of information, Physical Properties and Data of Optical Materials builds a thorough background for more than 100 optical materials and offers quick access to precise information. Surveying the most important and widely used optical materials, this handy reference includes data on a wide variety of metals, semiconductors, dielectrics, polymers, and other commonly used optical materials. For each material, the editors examine the crystal system; natural and artificial growth and production methods along with corrosives and processing; thermal, electrical, and mechanical properties; optical properties, such as transmittance and reflectance spectra, ranging from UV to IR wavelengths; and, where applicable, applications for spectroscopy and miscellaneous remarks such as handling concerns and chemical properties. Numerous tables illustrate important data such as numerical values of optical constants for important wavelength regions, extinction and absorption coefficients, and refractive index. Physical Properties and Data of Optical Materials offers a collection of data on an unprecedented variety of fundamental optical materials, making it the one quick-lookup guide that every optical scientist, engineer, and student should own.