多粒子物理学(第3版)(英文版)

本书自问世以来，一直是量子多体理论领域中最权威的著作之一。本书全面系统地讲解了格林函数方法在固体理论中的实际应用，给出了其在处理电子气、极化子、电子输运、光响应、超导和超流等实际问题时的具体过程，内容涵盖了固体多体理论中的很多论题，例如严格可解模型和强关联电子系统等。此次影印的是本书的第三版。作者对旧版中的若干章节进行了修订，介绍了许多新的研究成果，此外作者还新增了几个章节，例如不同的平均自由程，Hubbard模型、库仑阻塞和量子霍尔效应等。本书附有大量的习题和丰富的参考文献，是高年级本科生、研究生和科研人员学习固体多体理论和格林函数方法优秀的参考书。
本书特色：（1）内容非常丰富，选题先进，包含了固体量子多体理论的很多论题及其最新进展。（2）详细地讲解了处理多体问题时的实用方法和具体过程，以提高读者解决实际问题的能力。
读者对象：适用于理论物理学、凝聚态物理学等专业的高年级本科生、研究生和相关专业的科研人员。

1. Introductory Material
1.1. Harmonic Oscillators and Phonons
1.2. Second Quantization for Particles
1.3. Electron-Phonon Interactions
1.3.1. Interaction Hamiltonian
1.3.2. Localized Electron
1.3.3. Deformation Potential
1.3.4. Piezoelectric Interaction
1.3.5. Polar Coupling
1.4. Spin Hamiltonians
1.4.1. Homogeneous Spin Systems
1.4.2. Impurity Spin Models
1.5. Photons
1.5.1. Gauges
1.5.2. Lagrangian
1.5.3. Hamiltonian
1.6. Pair Distribution Function
Problems
2. Green's Functions at Zero Temperature.
2.1. Interaction Representation
2.1.1. Schr6dinger
2.1.2. Heisenberg
2.1.3. Interaction
2.2. S Matrix
2.3. Green's Functions
2.4. Wick's Theorem
2.5. Feynman Diagrams
2.6. Vacuum Polarization Graphs
2.7. Dyson's Equation
2.8. Rules for Constructing Diagrams
2.9. Time-Loop S Matrix
2.9.1. Six Green's Functions
2.9.2. Dyson's Equation
2.10. Photon Green's Functions
Problems
3. Nonzero Temperatures
3.1. Introduction
3.2. Matsubara Green's Functions
3.3. Retarded and Advanced Green's Functions
3.4. Dyson's Equation
3.5. Frequency Summations
3.6. Linked Cluster Expansions
3.6.1. Thermodynamic Potential
3.6.2. Green's Functions
3.7. Real-Time Green's Functions
3.7.1. Wigner Distribution Function
3.8. Kubo Formula for Electrical Conductivity
3.8.1. Transverse Fields, Zero Temperature
3.8.2. Nonzero Temperatures
3.8.3. Zero Frequency
3.8.4. Photon Self-Energy
3.9. Other Kubo Formulas
3.9.1. Pauli Paramagnetic Susceptibility
3.9.2. Thermal Currents and Onsager Relations
3.9.3. Correlation Functions
Problems
4. Exactly Solvable Models
4.1. Potential Scattering
4.1.1. Reaction Matrix
4.1.2. T Matrix
4.1.3. Friedel's Theorem
4.1.4. Impurity Scattering
4.1.5. Ground State Energy
4.2. Localized State in the Continuum
4.3. Independent Boson Models
4.3.1. Solution by Canonical Transformation.
4.3.2. Feynman Disentangling of Operators
4.3.3. Einstein Model
4.3.4. Optical Absorption and Emission
4.3.5. Sudden Switching
　　……
5. Homogeneous Electron Gas
6. Strong Correlations
7. Electron-Phonon Interaction
8. dc Conductivities
9. Optical Properties of Solids
10. Superconductivity
11. Superfluids
References
Author Index
Subject Index