Solid-State Physics

1. Chemical Bonding in Solids.- 1.1 The Periodic Table of the Elements.- 1.2 Covalent Bonding.- 1.3 Ionic Bonding.- 1.4 Metallic Bonding.- 1.5 The Hydrogen Bond.- 1.6 The van der Waals Bond.- Problems.- 2. Crystal Structures.- 2.1 The Crystal Lattice.- 2.2 Point Symmetry.- 2.2.1 Reflection in a Plane.- 2.2.2 Inversion.- 2.2.3 Rotation Axes.- 2.2.4 Rotation-Inversion Axes.- 2.3 The 32 Crystal Classes (Point Groups).- 2.4 The Significance of Symmetry.- 2.5 Simple Crystal Structures.- 2.5.1 The Face-Centered Cubic Structure.- 2.5.2 Hexagonal Close Packing.- 2.5.3 The Body-Centered Cubic Structure.- 2.5.4 The Diamond Structure.- 2.5.5 The Zinc Blende Structure.- 2.5.6 Ionic Structures.- Problems.- 3. Diffraction from Periodic Structures.- 3.1 General Theory of Diffraction.- 3.2 Periodic Structures and the Reciprocal Lattice.- 3.3 The Scattering Conditions for Periodic Structures.- 3.4 The Bragg Interpretation of the Laue Condition.- 3.5 Brillouin Zones.- 3.6 The Structure Factor.- 3.7 Methods of Structure Analysis.- 3.7.1 Types of Probe Beam.- 3.7.2 Procedures for Determining Structure.- Problems.- Panel I: Diffraction Experiments with Various Particles.- Panel II: X-Ray Interferometry and X-Ray Topography.- 4. Crystal Lattice Dynamics.- 4.1 The Potential.- 4.2 The Equation of Motion.- 4.3 The Diatomic Linear Chain.- 4.4 Scattering from Time-Varying Structures.- 4.5 Phonon Spectroscopy.- Problems.- Panel III: Raman Spectroscopy.- 5. Thermal Properties of Crystal Lattices.- 5.1 The Density of States.- 5.2 The Thermal Energy of a Harmonic Oscillator.- 5.3 The Specific Heat Capacity of the Lattice.- 5.4 Effects Due to Anharmonicity.- 5.5 Thermal Expansion.- 5.6 Heat Conduction by Phonons.- Problems.- Panel IV: Experiments at Low Temperatures.- 6. "Free" Electrons in Solids.- 6.1 The Free Electron Gas in an Infinite Square-Well Potential.- 6.2 The Fermi Gas at T = 0K.- 6.3 Fermi Statistics.- 6.4 The Specific Heat Capacity of Electrons in Metals.- 6.5 Electrostatic Screening in a Fermi Gas - The Mott Transition.- 6.6 Thermionic Emission of Electrons from Metals.- Problems.- 7. The Electronic Bandstructure of Solids.- 7.1 General Symmetry Properties.- 7.2 The Nearly-Free-Electron Approximation.- 7.3 The Tight-Binding Approximation.- 7.4 Examples of Bandstructures.- 7.5 The Density of States.- Problems.- Panel V: Photoemission Spectroscopy.- 8. Magnetism.- 8.1 Diamagnetism and Paramagnetism.- 8.2 The Exchange Interaction.- 8.3 Exchange Interaction Between Free Electrons.- 8.4 The Band Model of Ferromagnetism.- 8.5 The Temperature Behavior of a Ferromagnet in the Band Model.- 8.6 Ferromagnetic Coupling for Localized Electrons.- 8.7 Antiferromagnetism.- 8.8 Spin Waves.- Problems.- Panel VI: Magnetostatic Spin Waves.- Panel VII: Surface Magnetism.- 9. Motion of Electrons and Transport Phenomena.- 9.1 Motion of Electrons in Bands and the Effective Mass.- 9.2 Currents in Bands and Holes.- 9.3 Scattering of Electrons in Bands.- 9.4 The Boltzmann Equation and Relaxation Time.- 9.5 The Electrical Conductivity of Metals.- 9.6 Thermoelectric Effects.- 9.7 The Wiedemann-Franz Law.- Problems.- Panel VIII: Quantum Oscillations and the Topology of Fermi Surfaces.- 10. Superconductivity.- 10.1 Some Fundamental Phenomena Associated with Superconductivity.- 10.2 Phenomenological Description by Means of the London Equations.- 10.3 Instability of the "Fermi Sea" and Cooper Pairs.- 10.4 The BCS Ground State.- 10.5 Consequences of the BCS Theory and Comparison with Experimental Results.- 10.6 Supercurrents and Critical Currents.- 10.7 Coherence of the BCS Ground State and the Meissner-Ochsenfeld Effect.- 10.8 Quantization of Magnetic Flux.- 10.9 Type II Superconductors.- 10.10 Novel "High Temperature" Superconductors.- Problems.- Panel IX: One-Electron Tunneling in Superconductor Junctions.- Panel X: Cooper Pair Tunneling - The Josephson Effect.- 11. Dielectric Properties of Materials.- 11.1 The Dielectric Function.- 11.2 Absorption of Electromagnetic Radiation.- Panel XI: Spectroscopy with Photons and Electrons.- 11.3 The Dielectric Function for a Harmonic Oscillator.- 11.4 Longitudinal and Transverse Normal Modes.- 11.5 Surface Waves on a Dielectric.- 11.6 Reflectivity of a Dielectric Half-Space.- Panel XII: Infrared Spectroscopy.- Panel XIII: The Frustrated Total Reflection Method.- 11.7 The Local Field.- 11.8 The Polarization Catastrophe and Ferroelectrics.- 11.9 The Free Electron Gas.- 11.10 Interband Transitions.- 11.11 Excitons.- 11.12 Dielectric Energy Losses of Electrons.- Problems.- 12. Semiconductors.- 12.1 Data for a Number of Important Semiconductors.- 12.2 Charge Carrier Density in Intrinsic Semiconductors.- 12.3 Doping of Semiconductors.- 12.4 Carrier Densities in Doped Semiconductors.- 12.5 Conductivity of Semiconductors.- Panel XIV: The Hall Effect.- Panel XV: Cyclotron Resonance in Semiconductors.- 12.6 The p-n Junction.- 12.6.1 The p-n Junction in Thermal Equilibrium.- 12.6.2 The Biased p-n Junction - Rectification.- 12.7 Semiconductor Heterostructures and Superlattices.- Problems.- Panel XVI: Shubnikov-de Haas Oscillations and the Quantum Hall Effect.- Panel XVII: Semiconductor Epitaxy.- References.