Includes bibliographical references (p. -270) and index.
Introduction.- The Linear Dielectric Suspectibility.- The Classical Treatment of Free and Bound Charge Carriers.- Derivations from the Oscillator Model.- The Kramers-Kronig-Relations.- Planar Interfaces.- Thick Slabs and Thin Films.- Enhanced Difficulty: Gradient Index Films and Multilayers.- Special Geometries.- Einstein's Coefficients.- Semiclassical Treatment of the Dielectric Function.- Solid-State Options.- Some Basic Effects of Nonlinear Optics.
(source: Nielsen Book Data)
The book is intended to bridge the gap between fundamental physics courses (such as optics, electrodynamics, quantum mechanics, and solid state physics) and highly specialized literature on the spectroscopy, design, and application of optical thin film coatings. Basic knowledge from the above-mentioned courses is therefore presumed. Starting from fundamental physics, the book enables the reader to derive the theory of optical coatings and to apply it to practically important spectroscopic problems. Both classical and semi-classical approaches are included. Examples describe the full range of classical optical coatings in various spectral regions as well as highly specialized new topics such as rugate filters and resonant grating waveguide structures. (source: Nielsen Book Data)