Quantum MechanicsWorld Scientific Publishing Company, 1 maj 1986 - 436 This book is a distillation of Prof T Y Wu's fifty years of experience teaching quantum theory to many generations of physicists. Starting with chapters on classical physics and the old quantum theory, Prof Wu quickly develops Heisenberg's matrix mechanics and the Schroedinger equation. After a detailed treatment of the general formulation of quantum theory, standard discussions on Perturbation Theory and the Hydrogen Atom follow. A fairly exhaustive treatment of the Zeeman effect is to be found in these chapter. Many electron atoms are treated expertly. The former is treated with great depth; the latter is a good introduction to the subject. |
Spis treści
| 1 | |
Chapter 1 PreQuantum Mechanical Period19001925 | 30 |
Chapter 2 Matrix Mechanics | 85 |
Early Developments | 131 |
Chapter 4 Probability Postulate and Uncertainty Principle | 191 |
General Theory | 209 |
Stationary State Problem | 259 |
Chapter 7 TimeDependent Systems | 274 |
Chapter 8 The Hydrogen Atom | 307 |
Chapter 9 Two and ManyElectron Atoms | 329 |
Chapter 10 Quantum Mechanics of Molecules | 386 |
Name Index | 411 |
| 414 | |
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angular momentum antisymmetric basic Bohr Bohr's calculated canonical Chap classical dynamics classical physics commutation relation concept condition configuration constant coordinates correspondence principle defined diagonal eigenfunctions eigenkets eigenvalues Einstein Einstein-de Broglie relations electric electron spin energy expressed field frequency given H₁ Hamilton-Jacobi equation Hamiltonian Heisenberg hermitian operator hydrogen atom integral L₂ linear m₁ magnetic matrix elements matrix mechanics method molecule motion notation nucleus obtains orbital P. A. M. Dirac p₁ parity particle Phys Planck's Poisson brackets postulate probability problem quantization quantum mechanics quantum numbers quantum theory radiation representation result rotational scattering Schrödinger equation selection rules solution spin-orbit interaction symmetry t₁ Theorem transformation transition unitary variables vector velocity vibrational wave function wave mechanics Zeeman effect ΔΕ