This is an excellent set of physics lectures. Feynman was very talented at right to heart of the matter and making everything seem obvious. ( )

Indeholder "Feynman's Preface", "Foreword", "Chapter 1. Quantum Behavior", " 1-1 Atomic mechanics", " 1-2 An experiment with bullets", " 1-3 An experiment with waves", " 1-4 An experiment with electrons", " 1-5 The interference of electron waves", " 1-6 Watching the electrons", " 1-7 First principles of quantum mechanics", " 1-8 The uncertainty principle", "Chapter 2. The Relation of Wave and Particle Viewpoints", " 2-1 Probability wave amplitudes", " 2-2 Measurement of position and momentum", " 2-3 Crystal diffraction", " 2-4 The size of an atom", " 2-5 Energy levels", " 2-6 Philosophical implications", "Chapter 3. Probability Amplitudes", " 3-1 The laws for combining amplitudes", " 3-2 The two-slit interference pattern", " 3-3 Scattering from a crystal", " 3-4 Identical particles", "Chapter 4. Identical Particles", " 4-1 Bose particles and Fermi particles", " 4-2 States with two Bose particles", " 4-3 States with n Bose particles", " 4-4 Emission and absorption of photons", " 4-5 The blackbody spectrum", " 4-6 Liquid helium", " 4-7 The exclusion principle", "Chapter 5. Spin One", " 5-1 Filtering atoms with a Stern-Gerlach apparatus", " 5-2 Experiments with filtered atoms", " 5-3 Stern-Gerlach filters in series", " 5-4 Base states", " 5-5 Interfering amplitudes", " 5-6 The machinery of quantum mechanics", " 5-7 Transforming to a different base", " 5-8 Other situations", "Chapter 6. Spin One-Half", " 6-1 Transforming amplitudes", " 6-2 Transforming to a rotated coordinate system", " 6-3 Rotations about the z-axis", " 6-4 Rotations of 180 degrees and 90 degrees about y", " 6-5 Rotations about x", " 6-6 Arbitrary rotations", "Chapter 7. The Dependence of Amplitudes on Time", " 7-1 Atoms at rest; stationary states", " 7-2 Uniform motion", " 7-3 Potential energy; energy conservation", " 7-4 Forces; the classical limit", " 7-5 The 'precession' of a spin one-half particle", "Chapter 8. The Hamiltonian Matrix", " 8-1 Amplitudes and vectors", " 8-2 Resolving state vectors", " 8-3 What are the base states of the world?", " 8-4 How states change with time", " 8-5 The Hamiltonian matrix", " 8-6 The ammonia molecule", "Chapter 9. The Ammonia Maser", " 9-1 The states of an ammonia molecule", " 9-2 The molecule in a static electric field", " 9-3 Transitions in a time-dependent field", " 9-4 Transitions at resonance", " 9-5 Transitions off resonance", " 9-6 The absorption of light", "Chapter 10. Other Two-State Systems", " 10-1 The hydrogen molecular ion", " 10-2 Nuclear forces", " 10-3 The hydrogen molecule", " 10-4 The benzene molecule", " 10-5 Dyes", " 10-6 The Hamiltonian of a spin one-half particle in a magnetic field", " 10-7 The spinning electron in a magnetic field", "Chapter 11. More Two-State Systems", " 11-1 The Pauli spin matrices", " 11-2 The spin matrices as operators", " 11-3 The solution of the two-state equations", " 11-4 The polarization states of the photon", " 11-5 The neutral K-meson", " 11-6 Generalization to N-state systems", "Chapter 12. The Hyperfine Splitting in Hydrogen", " 12-1 Base states for a system with two spin one-half particles", " 12-2 The Hamiltonian for the ground state of hydrogen", " 12-3 The energy levels", " 12-4 The Zeeman splitting", " 12-5 The states in a magnetic field", " 12-6 The projection matrix for spin one", "Chapter 13. Propagation in a Crystal Lattice", " 13-1 States for an electron in a one-dimensional lattice", " 13-2 States of definite energy", " 13-3 Time-dependent states", " 13-4 An electron in a three-dimensional lattice", " 13-5 Other states in a lattice", " 13-6 Scattering from imperfections in the lattice", " 13-7 Trapping by a lattice imperfection", " 13-8 Scattering amplitudes and bound states", "Chapter 14. Semiconductors", " 14-1 Electrons and holes in semiconductors", " 14-2 Impure semiconductors", " 14-3 The Hall effect", " 14-4 Semiconductor junctions", " 14-5 Rectification at a semiconductor junction", " 14-6 The transistor", "Chapter 15. The Independent Particle Approximation", " 15-1 Spin waves", " 15-2 Two spin waves", " 15-3 Independent particles", " 15-4 The benzene molecule", " 15-5 More organic chemistry", " 15-6 Other uses of the approximation", "Chapter 16. The Dependence of Amplitudes on Position", " 16-1 Amplitudes on a line", " 16-2 The wave function", " 16-3 States of definite momentum", " 16-4 Normalization of the states in x", " 16-5 The Schrödinger equation", " 16-6 Quantized energy levels", "Chapter 17. Symmetry and Conservation Laws", " 17-1 Symmetry", " 17-2 Symmetry and conservation", " 17-3 The conservation laws", " 17-4 Polarized light", " 17-5 The disintegration of the Λ0", " 17-6 Summary of the rotation matrices", "Chapter 18. Angular Momentum", " 18-1 Electric dipole radiation", " 18-2 Light scattering", " 18-3 The annihilation of positronium", " 18-4 Rotation matrix for any spin", " 18-5 Measuring a nuclear spin", " 18-6 Composition of angular momentum", " 18-7 Added Note 1: Derivation of the rotation matrix", " 18-8 Added Note 2: Conservation of parity in photon emission", "Chapter 19. The Hydrogen Atom and The Periodic Table", " 19-1 Schrödinger's equation for the hydrogen atom", " 19-2 Spherically symmetric solutions", " 19-3 States with an angular dependence", " 19-4 The general solution for hydrogen", " 19-5 The hydrogen wave functions", " 19-6 The periodic table", "Chapter 20. Operators", " 20-1 Operations and operators", " 20-2 Average energies", " 20-3 The average energy of an atom", " 20-4 The position operator", " 20-5 The momentum operator", " 20-6 Angular momentum", " 20-7 The change of averages with time", "Chapter 21. The Schrödinger Equation in a Classical Context: A Seminar on Superconductivity", " 21-1 Schrödinger's equation in a magnetic field", " 21-2 The equation of continuity for probabilities", " 21-3 Two kinds of momentum", " 21-4 The meaning of the wave function", " 21-5 Superconductivity", " 21-6 The Meissner effect", " 21-7 Flux quantization", " 21-8 The dynamics of superconductivity", " 21-9 The Josephson junction", "Feynman's Epilogue", "Appendix - Chapter 34 and 35 of Volume II.", "Chapter 34. The Magnetism of Matter", " 34-1 Diamagnetism and paramagnetism", " 34-2 Magnetic moments and angular momentum", " 34-3 The precession of atomic magnets", " 34-4 Diamagnetism", " 34-5 Larmor's theorem", " 34-6 Classical physics gives neither diamagnetism nor paramagnetism", " 34-7 Angular momentum in quantum mechanics", " 34-8 The magnetic energy of atoms", "Chapter 35. Paramagnetism and Magnetic Resonance", " 35-1 Quantized magnetic states", " 35-2 The Stern-Gerlach experiment", " 35-3 The Rabi molecular-beam method", " 35-4 The paramagnetism of bulk materials", " 35-5 Cooling by adiabatic demagnetization", " 35-6 Nuclear magnetic resonance", "Index".

Jeg kan godt lide forordet, hvor baggrunden for forelæsningerne er ridset op. Appendix er to kapitler fra Volume II som bruges meget i dette Volume III. Så det er meget behageligt at de lige er taget med som appendix. ( )

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