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200 10$aPhysics, optics, and spectroscopy of materials /$fZeev Burshtein
210  1$aHoboken, New Jersey :$cJohn Wiley & Sons, Inc.,$d[2022]
210  4$d©2022
215   $a1 online resource (996 pages)
311 08$aPrint version: Burshtein, Zeev Physics, Optics, and Spectroscopy of Materials Newark : John Wiley & Sons, Incorporated,c2022 9781119768739 
327   $aIntro -- Table of Contents -- Title Page -- Copyright Page -- Introduction -- 1 Electromagnetic Radiation/Matter Interaction - A Classical Approach -- 1.1 Electromagnetic Radiation by Atoms and Molecules -- 1.2 Spectral Line Widths -- 1.3 Electromagnetic Radiation Absorption by Atoms and Molecules -- 1.4 Radiation Scattering by Atoms and Molecules -- 1.5 Reminder: Multipole Moments Expansion -- Exercises for Chapter 1 -- 2 Electromagnetic Radiation/Matter Interaction - A Semi?Quantum Approach -- 2.1 A Reminder of Perturbation Theory -- 2.2 A Reminder of Planck's Black?Body Radiation -- 2.3 An Atom or Molecule in an Electromagnetic Radiation Field -- 2.4 Stimulated Emission and Einstein's Coefficients -- 2.5 Radiation Absorption and Amplification in Matter -- 2.6 Black Body Radiation - Continuation and Completion -- Exercises for Chapter 2 -- 3 The Hydrogen Atom - Electrostatic Attraction Approximation -- 3.1 De Broglie Waves and Schrödinger's Equation -- 3.2 Differential Operators and Physical Quantities -- 3.3 Schrödinger Equation Solution for Hydrogen and Hydrogen?Like Atoms -- 3.4 Physical Meanings of Schrödinger Equation Solutions for Hydrogen?Like Atoms -- 3.5 Spectroscopy of Hydrogen and Hydrogen?Like Atoms -- 3.6 Selection Rules -- Exercises for Chapter 3 -- 4 Hydrogen Atom - Corrections to the Electrostatic Attraction Approximation -- 4.1 Angular Momentum and the Orbital Quantum Number -- 4.2 Mechanical Relativistic Correction to the Eigenenergies of the Hydrogen Atom -- 4.3 Electron Spinning -- 4.4 Combining Orbital Angular Momentum and Spin -- 4.5 Gyromagnetic Ratio and Spin/Orbit Coupling -- 4.6 Landé Factor -- 4.7 Lamb Shift -- 4.8 Selection Rules and Transition Probabilities -- 4.9 Static External Magnetic and Electric Fields: Zeeman and Stark Effects -- 4.10 The Fine Structure.
327   $a4.11 Appendix: Clebsch?Gordan Coefficients for Coupling of Two Angular Momentums -- Exercises for Chapter 4 -- 5 Many?Electron Atoms -- 5.1 Preamble -- 5.2 Helium?Like Atoms -- 5.3 Bosons, Fermions, and Pauli Exclusion Principle -- 5.4 Electronic Structure of Many?Electron Atoms -- 5.5 Excited?States Structure in Many?Electron Atoms -- Exercises for Chapter 5 -- 6 Electron Orbits in Molecules -- 6.1 Preamble -- 6.2 The Hydrogen Molecule Ion -- 6.3 Molecular Electronic Angular Momentum -- 6.4 Many?Electron Homonuclear Diatomic Molecules -- 6.5 Many?Electron Heteronuclear Diatomic Molecules -- 6.6 Multiatomic Molecules -- 6.7 Appendix: Calculation of an Infinitesimal Volume Element in Elliptic Coordinates -- Exercises for Chapter 6 -- 7 Molecular (Especially Diatomic) Internal Oscillations -- 7.1 Preamble -- 7.2 The Born?Oppenheimer Approximation -- 7.3 Vibrational and Rotational Modes of Diatomic Molecules -- 7.4 Vibrational/Rotational Absorption Spectra -- 7.5 Electronic Transitions and the Franck?Condon Principle -- Exercises for Chapter 7 -- 8 Internal Oscillations of Polyatomic Molecules -- 8.1 Preamble -- 8.2 Zero?Order Mechanical Energy Approximation of a Polyatomic Molecule -- 8.3 Molecular Vibrational Modes -- 8.4 Vibrational Energy Scheme -- 8.5 Rayleigh and Raman Scattering -- 8.6 Point Symmetry -- 8.7 Group Representations, Characters, and Reduction Equation -- 8.8 Similarity Classes, Irreducible Representations, and Character Tables -- 8.9 Selection Rules for Electric Dipole Absorption and Raman Scattering -- 8.10 Method for Calculation and Description of Molecular Vibrational Species -- 8.11 Examples of Molecular Vibrational Symmetry Species -- 8.12 Point Groups, Character Tables, and Selection Rules -- Exercises for Chapter 8 -- 9 Crystalline Solids -- 9.1 Preamble -- 9.2 Periodic Crystals.
327   $a9.3 Lattice?Vector and Lattice?Plane Orientations -- 9.4 The Reciprocal Lattice -- 9.5 Internal Crystalline Oscillations -- 9.6 Appendix: Intermediate Calculation for Justifying Eq. (9.11) -- Exercises for Chapter 9 -- 10 Dielectric Crystalline Solids -- 10.1 Light Propagation in a Dielectric Medium -- 10.2 Light Transition from Vacuum into a Dielectric Medium -- 10.3 Kramers?Kronig Relations -- 10.4 A Microscopic Model of the Dielectric Function -- 10.5 A Reminder: Gradient, Divergence, Rotor, and the Cauchy Equation -- Exercises for Chapter 10 -- 11 Crystalline Oscillation Species -- 11.1 Introduction -- 11.2 Crystalline Sites -- 11.3 Tabulation Method -- 11.4 Calculation of Crystalline Oscillation Species - An Example -- 11.5 Tabulation of Crystalline Space Group Properties -- Exercises for Chapter 11 -- 12 Atoms and Ions in Crystalline Sites -- 12.1 Introduction -- 12.2 Energy States of Alkali and Alkali?Like Atoms -- 12.3 Energy States of Many?Electron Atoms and Ions -- 12.4 Dopant Atoms or Ions in Crystalline Sites -- 12.5 Transition Probabilities and Selection Rules -- 12.6 Spectroscopic Examples -- 12.7 Appendix: An Integral Over Three Multiplied Spherical Harmonics -- Exercises for Chapter 12 -- 13 Non?Radiative and Mixed Decay Transitions -- 13.1 Non?Radiative Transitions Between Close Electronic States -- 13.2 Radiative Transition Lifetime and Optical Absorption and Emission Spectra -- 13.3 Multi?Phonon Non?Radiative Transitions -- Exercises for Chapter 13 -- 14 Basic Acquaintance with the Laser and Its Components -- 14.1 General Description -- 14.2 The Optical Cavity -- 14.3 The Prism -- 14.4 Reflection Grating -- 14.5 Fabry?Pérot Etalon -- 14.6 Brewster Window and a Brewster Plate -- 14.7 Loss Presentation in a Laser Cavity -- Exercises for Chapter 14 -- 15 Transverse Optical Modes and Crystal Optics -- 15.1 Preamble.
327   $a15.2 Transverse Single?Mode Gaussian Beam -- 15.3 Transverse Multi?Mode Beams -- 15.4 Selecting a Transverse Mode for a Laser Output -- 15.5 Lens Crossing of a Single?Mode Transverse Gaussian Beam -- 15.6 Multi?Mode Transverse Gaussian Beams -- 15.7 Crystal Optics -- 15.8 Retardation Plates -- Exercises for Chapter 15 -- 16 Pulsed High Power Lasers -- 16.1 Introduction -- 16.2 Passive Q?Switching Using a Saturable Light Absorber -- 16.3 Active Q?Switching Using Electrooptic Crystals -- 16.4 Mode?Locking -- Exercises for Chapter 16 -- 17 Frequency Conversions of Laser Beams -- 17.1 Non?Linear Crystals -- 17.2 Electromagnetic Wave Propagation in a Non?Linear Crystal -- 17.3 Optical Parametric Oscillations -- 17.4 A Reminder: Hyperbolic "Trigonometric" Functions -- Exercises for Chapter 7 -- 18 Examples of Various Laser Systems -- 18.1 Introduction -- 18.2 Helium?Neon Laser -- 18.3 Copper Vapor Laser -- 18.4 Hydrogen Fluoride Chemical Laser -- 18.5 Neodymium?YAG Laser -- 18.6 Dye Lasers -- 18.7 Diode Lasers -- Exercises for Chapter 18 -- Appendix A: Greek alphabet and phonetic names -- Appendix B: Table of physical constants -- Appendix C: Dirac ? function -- Appendix D: Literature references for further reading -- 1. Books -- 2. Journal publications -- Index -- End User License Agreement.
606   $aSpectrum analysis
606   $aOptics
606   $aDielectrics
615  0$aSpectrum analysis.
615  0$aOptics.
615  0$aDielectrics.
676   $a535.8/4
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