1 Second Quantisation1��1 Identical Particles1��2 The \"Continuous\" Fock Representation1��3 The \"Discrete\" Fock Representation1��4 Exercises1��5 Self-Examination Questions2 Many-Body Model Systems2��1 Crystal Electrons2��1��1 Non-interacting Bloch Electrons2��1��2 The Jellium Model2��1��3 The Hubbard Model2��1��4 Exercises2��2 Lattice Vibrations2��2��1 The Harmonic Approximation2��2��2 The Phonon Gas2��2��3 Exercises2��3 The Electron-Phonon Interaction2��3��1 The Hamiltonian2��3��2 The Effective Electron-Electron Interaction2��3��3 Exercises2��4 Spin Waves2��4��1 Classification of Magnetic Solids2��4��2 Model Concepts2��4��3 Magnons2��4��4 The Spin-Wave Approximation2��4��5 Exercises2��5 Self-Examination Questions3 Green's Funetions3��1 Preliminary Considerations3��1��1 Representations3��1��2 Linear-Response Theory3��1��3 The Magnetic Susceptibility3��1��4 The Electrical Conductivity3��1��5 The Dielectric Function3��1��6 Spectroscopies�� Spectral Density3��1��7 Exercises3��2 Double-Time Green's Functions3��2��1 Equations of Motion3��2��2 Spectral Representations3��2��3 The Spectral Theorem3��2��4 Exact Expressions3��2��5 The Kramers-Kronig Relations3��2��6 Exercises3��3 First Applications3��3��1 Non-Interacting Bloch Electrons3��3��2 Free Spin Waves3��3��3 The Two-Spin Problem3��3��4 Exercises3��4 The Quasi-Particle Concept3��4��1 One-Electron Green's Functions3��4��2 The Electronic Self-Energy3��4��3 Quasi-Particles3��4��4 Quasi-Particle Density of States3��4��5 Internal Energy3��4��6 Exercises3��5 Self-Examination Questions4 Systems of Interacting Particles4��1 Electrons in Solids4��1��1 The Limiting Case of an Infinitely Narrow Band4��1��2 The Hartree-Fock Approximation4��1��3 Electronic Correlations4��1��4 The Interpolation Method4��1��5 The Method of Moments4��1��6 The Exactly Half-filled Band4��1��7 Exercises4��2 Collective Electronic Excitations4��2��1 Charge Screening ��Thomas-Fermi Approximation��4��2��2 Charge Density Waves�� Plasmons4��2��3 Spin Density Waves�� Magnons4��2��4 Exercises4��3 Elementary Excitations in Disordered Alloys4��3��1 Formulation of the Problem4��3��2 The Effective-Medium Method4��3��3 The Coherent Potential Approximation4��3��4 Diagrammatic Methods4��3��5 Applications4��4 Spin Systems4��4��1 The Tyablikow Approximation4��4��2 \"Renormalised\" Spin Waves4��4��3 Exercises4��5 The Electron-Magnon Interaction4��5��1 Magnetic 4f Systems ��s-f-Model��4��5��2 The Infinitely Narrow Band4��5��3 The Alloy Analogy4��5��4 The Magnetic Polaron4��5��5 Exercises4��6 Self-Examination Questions5 Perturbation Theory ��T = 0��5��1 Causal Green's Functions5��I��1 \"Conventional\" Time-dependent Perturbation Theory5��1��2 \"Switching on\" the Interaction Adiabatically5��1��3 Causal Green's Functions5��1��4 Exercises5��2 Wick's Theorem5��2��1 The Normal Product5��2��2 Wick's Theorem5��2��3 Exercises5��3 Feynman Diagrams5��3��1 Perturbation Expansion for the Vacuum Amplitude5��3��2 The Linked-Cluster Theorem5��3��3 The Principal Theorem of Connected Diagrams5��3��4 Exercises5��4 Single-Particle Green's Functions5��4��1 Diagrammatic Perturbation Expansions5��4��2 The Dyson Equation5��4��3 Exercises5��5 The Ground-State Energy of the Electron Gas ��Jellium Model��5��5��1 First-Order Perturbation Theory5��5��2 Second-Order Perturbation Theory5��5��3 The Correlation Energy5��6 Diagrammatic Partial Sums5��6��1 The Polarisation Propagator5��6��2 Effective Interactions5��6��3 Vertex Function5��6��4 Exercises5��7 Self-Examination Questions6 Perturbation Theory at Finite Temperatures6��1 The Matsubara Method6��1��1 Matsubara Functions6��1��2 The Grand Canonical Partition Function6��1��3 The Single-Particle Matsubara Function6��2 Diagrammatic Perturbation Theory6��2��1 Wick's Theorem6��2��2 Diagram Analysis of the Grand-Canonical Partition Function6��2��3 Ring Diagrams6��2��4 The Single-Particle Matsubara Function6��3 Self-Examination QuestionsSolutions of the ExercisesIndex