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Physics of Condensed Matter : New Research.

By: Contributor(s): Material type: TextTextPublication details: Ashland : Arcler Press, 2019.Description: 1 online resource (365 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 1773615890
  • 9781773615899
Subject(s): Genre/Form: Additional physical formats: Print version:: Physics of Condensed Matter : New Research.DDC classification:
  • 530.4/1 23
LOC classification:
  • QC173.454
Online resources:
Contents:
Cover; Half Title Page; Title Page; Copyright Page; About the Authors; Table of Contents; List of Figures; List of Tables; List of Abbreviations; Preface; Section I: Introduction to Condensed Matters; Chapter 1 Overview; 1.1. Emergence of Condensed Matter Physics; 1.2. Introduction; 1.3. Condensed Matter; 1.4. Some Properties of Condensed Matter; 1.5. Many-Body Problem; 1.6. Crystal Formation; Chapter 2 Structure and Symmetry; 2.1. Structure Introduction; 2.2. The Lattice and its Types; 2.3. Symmetry Introduction; 2.4. Finite Structures; 2.5. Periodic Structures
2.6. Fourier Transformation of Structures2.7. Fourier Transformation Methods; 2.8. Quasi-Periodic Structures; 2.9. Stability of Structures; Chapter 3 Propagation of Waves in Different Structures; 3.1. Wave Behavior; 3.2. Electron Waves; 3.3. Elastic and Lattice Waves; 3.4. Waves in Periodic Structures; Chapter 4 Bloch Electrons and Their Transport Types; 4.1. Bloch Theorem; 4.2. Bloch Constant Vector of Wave; 4.3. Bloch Oscillations in Electric and Magnetic Fields; 4.4. Normal Transport; 4.5. Charge and Spin Transport; 4.6. Tunneling; Section II: Quantum of Condensed Matters
Chapter 5 Formation of Phonons and Second Quantization5.1. Overview; 5.2. Harmonic Phonons; 5.3. Phonons in Metals; 5.4. Electron and Electron Interactions; 5.5. Electron and Phonon Interactions; 5.6. Phonons in Semiconductors; 5.7. Lattice Dynamics in Classical Physics; 5.8. Modes of a Lattice; 5.9. Second Quantization; 5.10. Canonical Formalism; 5.11. Fock Space and Phonons; Chapter 6 Theory of Perturbation; 6.1. Phonon Lagrangian; 6.2. Dyson's Formula; 6.3. Wick's Theorem; 6.4. Perturbation Theory Interactions; Chapter 7 Green Function and Feynman Hellman's Theorem and Diagrams
7.1. Green's Function7.2. The Generating Functional; 7.3. Connected Diagrams; 7.4. Two-Point Green Function; 7.5. Spectral Representation; 7.6. Feynman Diagrams; 7.7. Loop Integrals; Chapter 8 Correlation Functions; 8.1. Toy Model and General Formulation; 8.2. Fluctuation-Dissipation Theorem; 8.3. Example of Perturbation; 8.4. Examples of Hydrodynamics; 8.5. Scattering Experiment (Inelastic); 8.6. Relaxation Rate; 8.7. Time Approximation; Section III: Approximate Models of Electrons; Chapter 9 Nearly-Free Electron Model; 9.1. Overview; 9.2. Perturbation Theory
9.3. Degenerate Perturbation Theory9.4. Non-Degenerate Perturbation Theory; 9.5. Approximation Band Structure of Empty Lattice; 9.6. Brillouin Zone Boundaries With Fermi Surfaces; 9.7. Scaling of Fermi Surfaces; Chapter 10 Pseudo-Potential Electron Model; 10.1. Introduction; 10.2. Pseudo-Potential Theorem; 10.3. Cancellation Theorem; 10.4. Ziman-Lloyd Pseudo-Potential; Chapter 11 Tight Binding Model; 11.1. Introduction; 11.2. For s Band Metal; 11.3. For Diamond-Structure Semiconductor; 11.4. Graphene (Example); Section IV: Condensed Matter Physics and Boltzmann Transport
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Print version record.

Cover; Half Title Page; Title Page; Copyright Page; About the Authors; Table of Contents; List of Figures; List of Tables; List of Abbreviations; Preface; Section I: Introduction to Condensed Matters; Chapter 1 Overview; 1.1. Emergence of Condensed Matter Physics; 1.2. Introduction; 1.3. Condensed Matter; 1.4. Some Properties of Condensed Matter; 1.5. Many-Body Problem; 1.6. Crystal Formation; Chapter 2 Structure and Symmetry; 2.1. Structure Introduction; 2.2. The Lattice and its Types; 2.3. Symmetry Introduction; 2.4. Finite Structures; 2.5. Periodic Structures

2.6. Fourier Transformation of Structures2.7. Fourier Transformation Methods; 2.8. Quasi-Periodic Structures; 2.9. Stability of Structures; Chapter 3 Propagation of Waves in Different Structures; 3.1. Wave Behavior; 3.2. Electron Waves; 3.3. Elastic and Lattice Waves; 3.4. Waves in Periodic Structures; Chapter 4 Bloch Electrons and Their Transport Types; 4.1. Bloch Theorem; 4.2. Bloch Constant Vector of Wave; 4.3. Bloch Oscillations in Electric and Magnetic Fields; 4.4. Normal Transport; 4.5. Charge and Spin Transport; 4.6. Tunneling; Section II: Quantum of Condensed Matters

Chapter 5 Formation of Phonons and Second Quantization5.1. Overview; 5.2. Harmonic Phonons; 5.3. Phonons in Metals; 5.4. Electron and Electron Interactions; 5.5. Electron and Phonon Interactions; 5.6. Phonons in Semiconductors; 5.7. Lattice Dynamics in Classical Physics; 5.8. Modes of a Lattice; 5.9. Second Quantization; 5.10. Canonical Formalism; 5.11. Fock Space and Phonons; Chapter 6 Theory of Perturbation; 6.1. Phonon Lagrangian; 6.2. Dyson's Formula; 6.3. Wick's Theorem; 6.4. Perturbation Theory Interactions; Chapter 7 Green Function and Feynman Hellman's Theorem and Diagrams

7.1. Green's Function7.2. The Generating Functional; 7.3. Connected Diagrams; 7.4. Two-Point Green Function; 7.5. Spectral Representation; 7.6. Feynman Diagrams; 7.7. Loop Integrals; Chapter 8 Correlation Functions; 8.1. Toy Model and General Formulation; 8.2. Fluctuation-Dissipation Theorem; 8.3. Example of Perturbation; 8.4. Examples of Hydrodynamics; 8.5. Scattering Experiment (Inelastic); 8.6. Relaxation Rate; 8.7. Time Approximation; Section III: Approximate Models of Electrons; Chapter 9 Nearly-Free Electron Model; 9.1. Overview; 9.2. Perturbation Theory

9.3. Degenerate Perturbation Theory9.4. Non-Degenerate Perturbation Theory; 9.5. Approximation Band Structure of Empty Lattice; 9.6. Brillouin Zone Boundaries With Fermi Surfaces; 9.7. Scaling of Fermi Surfaces; Chapter 10 Pseudo-Potential Electron Model; 10.1. Introduction; 10.2. Pseudo-Potential Theorem; 10.3. Cancellation Theorem; 10.4. Ziman-Lloyd Pseudo-Potential; Chapter 11 Tight Binding Model; 11.1. Introduction; 11.2. For s Band Metal; 11.3. For Diamond-Structure Semiconductor; 11.4. Graphene (Example); Section IV: Condensed Matter Physics and Boltzmann Transport

Chapter 12 Boltzmann Equation

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