48,95 €
48,95 €
inkl. MwSt.
Sofort per Download lieferbar
24 °P sammeln
48,95 €
Als Download kaufen
48,95 €
inkl. MwSt.
Sofort per Download lieferbar
24 °P sammeln
Jetzt verschenken
Alle Infos zum eBook verschenken
48,95 €
inkl. MwSt.
Sofort per Download lieferbar
Alle Infos zum eBook verschenken
24 °P sammeln
- Format: PDF
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei
bücher.de, um das eBook-Abo tolino select nutzen zu können.
Hier können Sie sich einloggen
Hier können Sie sich einloggen
Sie sind bereits eingeloggt. Klicken Sie auf 2. tolino select Abo, um fortzufahren.
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei bücher.de, um das eBook-Abo tolino select nutzen zu können.
This book provides an accessible treatment of non-relativistic and relativistic quantum mechanics.
- Geräte: PC
- ohne Kopierschutz
- eBook Hilfe
- Größe: 25.27MB
Andere Kunden interessierten sich auch für
- Lukong Cornelius FaiQuantum Mechanics (eBook, ePUB)48,95 €
- Minjoon KouhThermal Physics Tutorials with Python Simulations (eBook, PDF)52,95 €
- Marc J. AssaelCommonly Asked Questions in Thermodynamics (eBook, PDF)48,95 €
- Jonathan DemkoCryogenic Heat Management (eBook, PDF)48,95 €
- Patricia FaiscaA Concise Introduction to Thermodynamics for Physicists (eBook, PDF)48,95 €
- Jean-Philippe AnsermetSpintronics (eBook, PDF)79,95 €
- Andrew RexFinn's Thermal Physics (eBook, PDF)57,95 €
-
-
-
This book provides an accessible treatment of non-relativistic and relativistic quantum mechanics.
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis
- Seitenzahl: 552
- Erscheinungstermin: 1. Juni 2022
- Englisch
- ISBN-13: 9781000590302
- Artikelnr.: 63752266
- Verlag: Taylor & Francis
- Seitenzahl: 552
- Erscheinungstermin: 1. Juni 2022
- Englisch
- ISBN-13: 9781000590302
- Artikelnr.: 63752266
- Herstellerkennzeichnung Die Herstellerinformationen sind derzeit nicht verfügbar.
Lukong Cornelius Fai is professor of theoretical physics at the Department of Physics, Faculty of Sciences, University of Dschang. He is Head of Condensed Matter and Nanomaterials as well as Mesoscopic and Multilayer Structures Laboratory. He was formerly a senior associate at the Abdus Salam International Centre for Theoretical Physics (ICTP), Italy. He holds a Masters of Science in Physics and Mathematics (June 1991) as well as a Doctor of Science in Physics and Mathematics (February 1997) from Moldova State University. He is an author of over a hundred and seventy scientific publications and five textbooks
Chapter 1. Quantum Mechanics Basic Concepts.
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 1. Quantum Mechanics Basic Concepts.
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 1. Quantum Mechanics Basic Concepts.
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 1. Quantum Mechanics Basic Concepts.
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials
Chapter 2. Schrödinger Equation.
Chapter 3. Momentum Operator. Chapter 4. Total Angular Momentum.
Chapter 5. One-Dimensional Motion General Principles.
Chapter 6. Schrödinger Equation.
Chapter 7. Representation Theory.
Chapter 8. Quantum Mechanics Approximate Methods.
Chapter 9. Many-Particle System.
Chapter 10. Approximate Method for the Helium Atom.
Chapter 11. Approximate Method for the Hydrogen Molecule.
Chapter 12. Scattering Theory.
Chapter 13. Polaron Theory.
Chapter 14. Case of an Electron.
Chapter 15. Klein-Gordon Equation.
Chapter 16. Dirac Equation.
Chapter 17. Probability and Current Densities.
Chapter 18. Electron Spin in the Dirac Theory.
Chapter 19. Free Electron State with Defined Momentum-Positronium Motion.
Chapter 20. Dirac Equation.
Chapter 21. Motion in a Magnetic Field.
Chapter 22. Gamma Functions.
Chapter 23. Confluent Hypergeometric Functions.
Chapter 24. Cylindrical Functions.
Chapter 25. Orthogonal Polynomials