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Fundamentals of the Optics of Materials : Tutorial and Problem Solving / Vladimir I. Gavrilenko, Volodymyr S. Ovechko
Mitwirkende(r): Resource type: Ressourcentyp: Buch (Online)Buch (Online)Sprache: Englisch Verlag: Singapore : Jenny Stanford Publishing, [2024]Beschreibung: 1 Online-Ressource (390 p.)ISBN:- 1000523314
- 9781003256946
- 1003256945
- 9781000523355
- 1000523357
- 9781000523317
- 620.11295 23/eng/20231009
- 620.1/1295 23/eng/20231009
- QC374
Inhalte:
Zusammenfassung: This textbook showcases the rapidly developing field of materials optics. It is aimed at a broad audience as the readers require only university entry level knowledge of physics, chemistry, and optics. It overviews the basics of optical engineering and the typical and widely used applications of materials optics, with the first general chapters corresponding to the standard university courses, targeting bachelor's and master's degrees in physics. The next few chapters present the modern developments in materials optics, such as nano-plasmonics, nano-photonics, and optical properties of nano-sized materials, intended for readers familiar with the basic elements of quantum mechanics. Some more specialized chapters address recent developments in fields such as optics of solid surfaces, plasma optics, optics of composites, alloys, and metamaterials; optics of anisotropic materials; optics of organic and biological materials; and relativistic effects in optics. The appendices present a more advanced description of selected topics, with important reference materials, subject index, and extended list of publications, as well as numerous examples and problems to better orient readers interested in gaining further knowledge of the subjectPPN: PPN: 190796309XPackage identifier: Produktsigel: ZDB-4-NLEBK | BSZ-4-NLEBK-KAUB
Cover -- Half Title -- Title Page -- Copyright Page -- Dedicated -- Table of Contents -- Preface -- Chapter 1: Basics of the Light Interaction with Matter -- 1.1: Introduction: Description of the Electromagnetic Field in Medium -- 1.2: Linear Optical Response: Classical Picture -- 1.3: Linear Optical Response: Quantum Mechanical Picture -- 1.4: Dispersion Relations for Rare Gas: Lorentz-Lorenz Formulae -- 1.5: Review Questions and Exercises -- 1.5.1: Complex Dielectric Susceptibility -- 1.5.2: Dielectric Permittivity and Refractive Index -- 1.5.3: Reflection Coefficient for Germanium
1.5.4: Group Velocity -- 1.5.5: Refractive Index of Iodine -- 1.5.6 Refractive Index Dispersion -- Chapter 2: Nonlinear Light Interaction with Matter -- 2.1: Introduction -- 2.2: Nonlinear Processes -- 2.3: Nonlinear Optical Processes Classification -- 2.4: Classic Theory of Nonlinear Optical Response -- 2.5: Quantum Picture: Electron Charge Density within the Perturbation Theory -- 2.6: Review Questions and Exercises -- 2.6.1: Relationship between Linear and Nonlinear Optical Susceptibilities -- 2.6.2: Quadratic Nonlinear Dielectric Polarization -- 2.6.3: Second Harmonic Generation
2.6.4: Parametric Frequency Mixing -- 2.6.5: Phase Modulation -- 2.6.6: Relationship between Nonlinear Functions -- Chapter 3: Fundamentals of Electron Energy Structure and Optics of Molecules -- 3.1: Introduction -- 3.2: Electron Energy Structure of Simple Molecules -- 3.2.1: A Homonuclear Diatomic Molecule: The Hydrogen Molecule -- 3.2.2: Heteronuclear Diatomic Molecule -- 3.3: Linear Combination of Atomic Orbitals Method -- 3.3.1: Electron Energy Structure of Methane Molecule -- 3.4: First Principles Methods in Computational Materials Science -- 3.4.1: Thomas-Fermi Approximation
3.4.2: First Principles Methods Based on the Density Functional Theory -- Chapter 4: Optical Absorption and Fluorescence of Materials -- 4.1: Light Absorption of Materials -- 4.2: Interaction of Electromagnetic Radiation with Atom -- 4.3: Light Emission and Absorption by Atom -- 4.4: Einstein Coefficients for Condensed Matter -- 4.5: Principles of the Signal Processing in Optics -- 4.5.1: Basic Principles of Operation in Optical Spectrometry -- 4.5.2: Optical Response Function: Inverse Problem in Optics -- 4.5.3: Tikhonov Method of Solution Regularization -- 4.5.4: Fourier Transform Spectrometer
4.5.5: Non-harmonic Analysis in Optical Spectroscopy -- 4.6: Photoluminescence -- 4.7: Luminescence Kinetics -- 4.7.1: Rate Measurement of Photonic Processes in Materials -- 4.7.2: Stern-Folmer Equation -- 4.7.3: Chemical Reactions Limited by Diffusion -- 4.7.4: Energy Transfer in Luminescence -- 4.8: Measurements of Luminescence -- 4.9: Review Questions and Exercises -- 4.9.1: Bouguer-Lambert Law -- 4.9.2: Amplification by Optical Pumping -- 4.9.3: Homogeneous Spectral Line Broadening by Finite Lifetime -- 4.9.4: Inhomogeneous Spectral Line Broadening by Thermal Motion
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