Fundamentals of Phosphors
Coordonnateurs : Yen William M., Shionoya Shigeo(decease), Yamamoto Hajime
Drawing from the second edition of the best-selling Handbook of Phosphors, Fundamentals of Phosphors covers the principles and mechanisms of luminescence in detail and surveys the primary phosphor materials as well as their optical properties. The book addresses cutting-edge developments in phosphor science and technology including oxynitride phosphors and the impact of lanthanide level location on phosphor performance.
Beginning with an explanation of the physics underlying luminescence mechanisms in solids, the book goes on to interpret various luminescence phenomena in inorganic and organic materials. This includes the interpretation of the luminescence of recently developed low-dimensional systems, such as quantum wells and dots. The book also discusses the excitation mechanisms by cathode-ray and ionizing radiation and by electric fields to produce electroluminescence.
The book classifies phosphor materials according to the type of luminescence centers employed or the class of host materials used and interprets the optical properties of these materials, including their luminescence characteristics and mechanisms. Placing a strong emphasis on those materials that are important from a practical point of view, the coverage also includes those possessing no possibility for practical use but are important from a theoretical standpoint.
Date de parution : 09-2019
17.8x25.4 cm
Date de parution : 12-2006
Ouvrage de 376 p.
17.8x25.4 cm
Thèmes de Fundamentals of Phosphors :
Mots-clés :
Luminescence Centers; Configurational Coordinate Model; Rare Earth Ions; Conduction Band; Luminescence Spectra; Crystal Field; Trivalent Rare Earth Ions; Spin Orbit Interaction; Isoelectronic Trap; Donor Acceptor Pair; Valence Band; Free Excitons; Thermal Quenching; Thin Film Electroluminescence; Resonant Energy Transfer; External Quantum Efficiency; Alkali Halide; Dynamical Jahn Teller Effect; Zinc Blende Structure; Time Resolved Emission Spectrum; DAP Emission; Net Acceptor Concentration; Crystal Field Splitting; LPE; Semiconductor Lasers