Preface; Prolegomenon; 1. The Harmonic Oscillator: Classical verses Quantum; 2. The Mathematical Structure of Quantum Mechanics; 3. Observables and Expectation Values; 4. The Projection Postulate Examined; 5. Rigged Hilbert Space and the Dirac Calculus; 6. A Review of Classical Mechanics; 7. Hamilton-Jacobi Theory *; 8. Classical Mechanics Regain'd; 9. Wave Mechanics I: Heisenberg Uncertainty; 10. Wave Mechanics II: The Fourier Transform; 11. Wave Mechanics III: The Quantum Oscillator; 12. Angular Momentum I: Basics; 13. Angular Momentum II: Representations of su(2); 14. Angular Momentum III: The Central Force Problem; 15. Wave Mechanics IV: The Hydrogenic Potential; 16. Wave Mechanics V: Hidden Symmetry Revealed; 17. Wave Mechanics VI: Hidden Symmetry Solved; 18. Angular Momentum IV: Addition Rules and Spin; 19. Wave Mechanics VII: Pauli's Spinor Theory; 20. Clifford Algebras and Spin Representations *; 21. Many-Particle Quantum Systems; 22. The EPR Argument and Bell's Inequalities; 23. Ensembles and Density Operators; 24. Bosons and Fermions; 25. The Fock Space for Indistinguishable Quanta; 26. An Introduction to Quantum Statistical Mechanics; 27. Quantum Dynamics; 28. Unitary Representations and Conservation Laws; 29. The Feynman Formulation of Quantum Mechanics; 30. A Mathematical Interlude: Gaussian Integrals; 31. Evaluating Path Integrals I; 32. Evaluating Path Integrals II; Epilogue; Resources for Individual Exploration; Bibliography; Index.
A leisurely but mathematically honest presentation of quantum mechanics for graduate students in mathematics with an interest in physics.
Philip L Bowers is the Dwight B. Goodner Professor of Mathematics at Florida State University.
'Quantum mechanics lies at the foundation of science, as well as
inspiring a great deal of mathematics. Lectures on Quantum
Mechanics provides mathematicians and mathematics students with a
very readable exposition of the subject, including the mathematical
clarity missing from the physics textbooks.' Peter Woit, Columbia
University
'The author of this non-traditional textbook for mathematicians
explains carefully how mathematical concepts can be used to encode
physical content of quantum mechanics. The topics are very well
chosen and ordered. All chapters are mostly independent, allowing
readers to get to the heart of the subject quickly and
nonlinearly.' Phan Thành Nam, LMU Munich
'… this is a useful text that integrates mathematics and quantum
mechanics, one that promises to help first-year graduate students
ready themselves for advanced research. Recommended.' M. O. Farooq,
Choice
Ask a Question About this Product More... |