Part D: Multi-particle states
Graduate Quantum Mechanics Lecture Notes
Preface
1
Introduction
Part A: Foundations of quantum mechanics
2
Hilbert spaces and postulates of QM
3
The two-state system
4
Time evolution in quantum mechanics
Part B: Quantum mechanics in one dimension
5
Position and momentum operators
6
The quantum simple harmonic oscillator
7
Time-evolution pictures and classical from quantum
8
Wave mechanics and probability currents
9
Symmetry in quantum mechanics
10
Capstone example: the ammonia maser
Part C: Quantum mechanics in three dimensions
9
Symmetry in quantum mechanics
12
Rotational symmetry
13
Wave mechanics in three dimensions
14
Spin in quantum mechanics
15
Addition of angular momentum
Part D: Multi-particle states
16
Entanglement
17
Density matrix formalism
18
Aspects of time evolution and density matrices
19
Identical particles
Part E: Approximation methods, part I
20
WKB approximation
21
Time-independent perturbation theory
22
Degenerate-state perturbation theory
23
A deep dive into hydrogen
24
Variational methods
25
The helium atom
Part F: More symmetries in quantum mechanics
26
Propagators and path integration
27
Gauge symmetry
28
Spherical tensors and selection rules
29
The Wigner-Eckart theorem
Part G: Approximation methods, part II
30
Time-dependence: sudden and adiabatic approximations
31
Time-dependent perturbation theory
32
Semi-classical electromagnetism
33
Electromagnetic transitions in atoms and molecules
Part H: Scattering theory
34
Scattering in one-dimensional systems
35
Scattering in three-dimensional systems
36
Scattering in perturbation theory
Appendices
A
Quick review for hydrogenic atoms
B
Compact review of fall semester
C
Invitation to quantum field theory
Part D: Multi-particle states
15
Addition of angular momentum
16
Entanglement