Preface

1 Introduction

　1.1 Spontaneously broken symmetry

　1.2 Tracking broken symmetry: order parameter

　1.3 Beyond broken symmetry

　References

2 Non interacting elearon gas

　Problems

3 Born—Oppenheimer approximation

　3.1 Basic Hamiltonian

　3.2 Adiabatic approximation

　3.3 Tight—binding approximation

　Problem

　References

4 Second quantization

　4.1 Bosons

　4.2 Fermions

　4.3 Fermion operators

　Problems

　References

5 Hartree—Fock approximation

　5.1 Non—interacting limit

　5.2 Hartree—Fock approximation

　5.3 Diagrams

　Problem

　References

6 Interacting electron gas

　6.1 Uniform electron gas

　6.2 Hartree—Fock excitation spectrum

　6.3 Cohesive energy of metals

　Summary

　Problems

　References

7 Local magnetic moments in metals

　7.1 Local moments: phenomenology

　7.2 Impurity density ofstates

　7.3 Green functions

　7.4 Friedel's sum rule and local moments

　Summary

　Appendix to Chapter 7: Luttinger's theorem

　Problems

　References

8 Quenching of local moments：the Kondo problem

　8.1 The Kondo Hamiltonian

　8.2 Why is J negative？

　8.3 Scattering and the resistivity minimum

　8.4 Electron—impurity scattering amplitudes

　8.5 Kondo temperature

　8.6 Poor Man's scaling

　Summary

　Appendix to Chapter 8: the Schrieffer—Wolff transformation

　Problems

　References

9 Screening and plasmons

　9.1 Thomas—Fermiscreening

　9.2 Plasma oscillations and collective coordinates

　9.3 Linear response theory

　9.4 Dielectric response function

　9.5 Kubo formula: electrical conductivity

　9.6 Stopping power of a plasma

　Summary

　Problems

　References

10 Bosonization

　10.1 Luttingerliquid

　10.2 Bosonization of Luttinger model

　10.3 Pair binding: can electrons do it alone？

　10.4 Excitation spectrum

　Summary

　Problems

　References

11 Electron—lattice interactions

　11.1 Harmonic chain

　11.2 Acoustic phonons

　11.3 Electron—phonon interaction

　11.4 Ultrasonic attenuation

　11.5 Electrical conduction

　Summary

　Problems

　References

12 Superconductivity in metals

　12.1 Superconductivity：phenomenology

　12.2 Electron—phonon effective interaction

　12.3 Model interaction

　12.4 Cooperpairs

　12.5 Fermi liquid theory

　12.6 Pair amplitude

　12.7 BCS ground state

　12.8 Pair fluctuations

　12.9 Ground state energy

　12.10 Critical magnetic field

　12.11 Energygap

　12.12 Quasi—particle excitations

　12.13 Thermodynamics

　12.14 Experimental applications

　12.15 Josephson tunneling

　Summary

　Problems

　References

13 Disorder：localization and exceptions

　13.1 Primer on localization

　13.2 Return probability: localization criterion

　13.3 Weak localization

　13.4 Scalingtheory

　13.5 Exceptions to localization

　Summary

　Problems

　References

14 Quantum phase transitions

　14.1 Quantum rotor model

　14.2 Scaling

　14.3 Mean—field solution

　14.4 Landau—Ginsburg theory

　14.5 Transport properties

　14.6 Experiments

　14.7 Scaling and T—linear resistivity

　Problems

　References

15 Quantum Halland other topological states

　15.1 What is the quantum Hall effect？

　15.2 Landaulevels

　15.3 The role of disorder

　15.4 Currents at the edge

　15.5 Topological insulators

　15.6 Laughlin liquid

　Summary

　Problems

　References

16 Electronsat strong coupling：Mottness

　16.1 Bandinsulator

　16.2 Mott's problem

　16.3 Much ado about zeros: Luttinger surface

　16.4 Beyond the atomic limit: Heisenberg versus Slater

　16.5 Dynamical spectral weight transfer

　16.6 Epilogue: 1=2—1

　Problems

　References

Index