Quantum Mechanics for Applied Nanotechnology
Clasificación: | Libro Electrónico |
---|---|
Autor principal: | |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Ashland :
Arcler Press,
2019.
|
Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Half Title Page; Title Page; Copyright Page; About the Author; Table of Contents; List of Figures; Preface; Chapter 1 Basics of Quantum Mechanics; 1.1. Quantum Physics; 1.2. States of Quantum Physics; 1.3. Operators of Quantum; 1.4. Postulates of Quantum Mechanics; 1.5. Schrodinger's Time-Dependent Equation; 1.6. Schrodinger's Time Independent Equation; 1.7. Traveling Waves in Quantum Physics; 1.8. Linear Harmonic Oscillator; 1.9. Lagrangian Mechanics; 1.10. Success and Failures of Quantum Physics; Chapter 2 Radiation; 2.1. Introduction; 2.2. Cavity/Black Body Radiation
- 2.3. Rayleigh-Jeans Radiation Law2.4. Planck's Equation; 2.5. Planck's Radiation Law; Chapter 3 Particles; 3.1. Introduction; 3.2. Classical Description of State of Particle; 3.3. Single Particle Wave Function; 3.4. Free Particle Wave Function; 3.5. 1-D Well With Infinitely High Barriers; 3.6. Well With Finite Barrier Height; 3.7. Davison Germer Experiment; Chapter 4 Wave; 4.1. Introduction; 4.2. Wave-Particle Duality Using Wave Function In Quantum; 4.3. Uncertainty And Indeterminacy; 4.4. Time-Energy Uncertainty Relation; 4.5. Fourier Synthesis; 4.6. Wave Packets; 4.7. Berkeley Experiment
- 4.8. Diffraction Of Matter WavesChapter 5 Operators and Expectation Values; 5.1. Dirac Notation; 5.2. Bra And Ket Vectors; 5.3. Commutators; 5.4. Non-Commuting Operators; 5.5. Commutators Involving Products of Operators; 5.6. Hermitian Operator; 5.7. Position Operator; 5.8. Momentum Operator; 5.9. Time Evolution Operator; 5.10. Spin Operators; 5.11. Harmonic Oscillator Related to Quantum; 5.12. Tensor Operator; 5.13. Spherical Tensor Operator; Chapter 6 Perturbation Theory; 6.1. Time-Dependent Theory; 6.2. Golden Rules Of Fermi; 6.3. Transition Rates (Radiative); 6.4. Rules Of Selection
- 6.5. Time-Independent Theory6.6. Quadratic And Linear Stark Effect; 6.7. Degenerate Theory Of Perturbation; 6.8. Zeeman Effect; 6.9. Paschen-Back Effect In Diatomic Molecules; 6.10. Estimation Of Energy Levels; 6.11. Hydrogen Gross Structure; 6.12. Hydrogen Fine Structure; Chapter 7 Relativistic Quantum Mechanics; 7.1. Lorentz Group; 7.2. Tensors, Vectors, And States Space; 7.3. Electrodynamics Of Relativistic Quantum Mechanics; 7.4. Lorentz Transformation Introduction; 7.5. Equations of Klein-Gordon; 7.6. Dirac; Chapter 8 Electronic Characteristics of Solids; 8.1. Drude Model
- 8.2. Relaxation Time Approximation8.3. Drude Model Failure; 8.4. Hall Effect; 8.5. Sommerfeld Model; 8.6. Fermi Dirac Function; 8.7. Bloch's Theorem; 8.8. Electronic Band Structure; 8.9. Free Electron Model Introduction; 8.10. Dispersion Relation; Chapter 9 Scattering Theory And Adiabatic Principle; 9.1. Operators of Scattering; 9.2. Matrix of Scattering; 9.3. Optical Theorem; 9.4. Expansion of Waves Partially; 9.5. Scattering at very Low Energy; 9.6. Resonant Scattering; 9.7. Breit-Wigner Resonances; 9.8. Scattering Electrons Off Hydrogen; 9.9. Adiabatic Principle Derivation