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| * '''Lecture 10''', ~-Feb 7-~: <<la("Lecture10v2.pdf", "Quantum Statistics: Bosons")>> (<<la("Lecture10ppt.pdf", "ppt format")>>) | * '''Lecture 10''', ~-Feb 7-~: <<la("Lecture10v3.pdf", "Quantum Statistics: Bosons")>> (<<la("Lecture10ppt.pdf", "ppt format")>>) * '''Lecture 11''', ~-Feb 12-~: <<la("Lecture11.pdf", "Solid State: Molecules, Rotation, and Vibration")>> (<<la("Lecture11ppt.pdf", "ppt format")>>) * '''Lecture 12''', ~-Feb 14-~: <<la("Lecture12.pdf", "Solid State: Crystals, Energy bands, and Conduction")>> (<<la("Lecture12ppt.pdf", "ppt format")>>) * '''Lecture 13''', ~-Feb 19-~: <<la("Lecture13.pdf", "Solid State: Semiconductor Theory and Devices and Superconductivity")>> (<<la("Lecture13ppt.pdf", "ppt format")>>) * '''Lecture 16''', ~-Feb 28-~: <<la("Lecture16v2.pdf", "Nuclear Physics: Nuclear structure, properties, and models")>> (<<la("Lecture16ppt.pdf", "ppt format")>>) * '''Lecture 17''', ~-Mar 5-~: <<la("Lecture17v3.pdf", "Nuclear Physics: nuclear decays")>> (<<la("Lecture17ppt.pdf", "ppt format")>>) |
Lecture Notes
Lecture 1, Jan 8: Wave, Schrodinger Eq, Bound state and unbound state (ppt format)
Lecture 2, Jan 10: Schrodinger Equation: Particle in 1d/3d infinite well and Hydrogen atom (ppt format)
Lecture 3, Jan 15: Hydrogen atom (ppt format)
Lecture 4, Jan 17: Hydrogen atom: Electron whereabouts and Hydrogenlike atoms (ppt format)
Lecture 5, Jan 22: Conservation and invariance, Spin, LS quantization, and Periodic table (ppt format)
Lecture 6, Jan 24: Angular momentum under magnetic fields (ppt format)
Lecture 8, Jan 31: Classical and Quantum Statistics (ppt format)
Lecture 9, Feb 5: Quantum Statistics: Fermions (ppt format)
Lecture 10, Feb 7: Quantum Statistics: Bosons (ppt format)
Lecture 11, Feb 12: Solid State: Molecules, Rotation, and Vibration (ppt format)
Lecture 12, Feb 14: Solid State: Crystals, Energy bands, and Conduction (ppt format)
Lecture 13, Feb 19: Solid State: Semiconductor Theory and Devices and Superconductivity (ppt format)
Lecture 16, Feb 28: Nuclear Physics: Nuclear structure, properties, and models (ppt format)
Lecture 17, Mar 5: Nuclear Physics: nuclear decays (ppt format)