重正化群理論——對實驗磁學的影響（英文影印版）

磁學的自旋波理論和超導的BCS理論是典型的重整化理論之前的理論。這兩個理論都只考慮了原子論的（離散化的）相互作用而沒有考慮連續固體的能量自由度。從Kenneth G. Wilson（1982年諾貝爾獎得主）的先驅工作開始，我們知道了連續固體的一個特殊的的對稱性：長度標度變換不變性。 本書綜述了近50年來固體物理的實驗，並用唯象的方式指出磁序和普通超導的動力學出現主要受連續固體的場論粒子而不是磁子或Cooper對的控制。在磁序中相關的粒子稱作GSW玻色子，在超導里相關的粒子稱作SC玻色子。

1 Introduction

2 History of Conventional Spin Wave Theory

2.1 Theoretical and Experimental Confusions

2.2 Problems with the Macroscopic Magnetization

3 Basic Issues of Renormalization Group (RG) Theory

3.1 Dynamics of Non Magnetic Solids

3.2 Dynamics of Ordered Magnets

4.Universality

4.1.Non-Magnetic Solids

4.2 Ordered Magnets

5 Microscopic Processes

6 Non-Relevant Magnons

7 Crossover Phenomena

7.1 Amplitude Crossover (AC)

7.2 Quantum State Crossover (QS)

7.3 Crossover Between Stable Fixed Points (SFP)

7.4 Symmetry Crossover (SC)

7.5 Dimensionality Crossover (DC)

8 Metastability of Universality Classes

9 Relevant and Non-Relevant Interactions

10 Temperature Dependence of the Magnon Excitation Spectra

11 Magnetic Heat Capacity

11.1 NonRelevant Magnetic Heat Capacity for T →0

12 Experimental Verification of GSW Bosons

13 Magnets With and Without Magnon Gap (Goldstone Mode)

13.1 Isotropic Magnets with Half-Integer Spin (T 2 Universality Class)

13.2 Isotropic Magnets with Integer Spin (T 9/2 Universality Class)

13.3 Two-Dimensional Magnets with Half-Integer Spin (T 3/2 Universality Class)

13.4 Two-Dimensional Magnets with Integer Spin (T 2 Universality Class)

13.5 One-Dimensional Magnets with Half-Integer Spin (T 5/2 Universality Class)

13.6 One-Dimensional Magnets with Integer Spin (T 3 Universality Class)

13.7 Field Dependence of the Classical Magnon Spectrum

14 Microscopic Details: Spin Structure, Site Disorder, Two Order Parameters .

15 The Critical Magnetic Behaviour

15.1 Isotropic 3D Magnets with Half-Integer Spin (T 2 Universality Class)

15.2 Anisotropic 3D Magnets with Half-Integer Spin (T 3/2 Universality Class)

15.3 Isotropic 3D Magnets with Integer Spin (T 9/2 Universality Class)

15.4 Anisotropic 3D Magnets with Integer Spin (T 2 Universality Class)

15.5 Amorphous Ferromagnets

15.6 Two-Dimensional Magnets

15.7 One-Dimensional Magnets

16 Thermal Lattice Expansion and Magnetostriction

16.1 Spontaneous Magnetostriction

16.2 Thermal Lattice Expansion of Non-Magnetic Solids

17 The Total Energy Content

11.2 Relevant Magnetic Heat Capacity for T →0.

18 Superconductivity

18.1 Superconducting Heat Capacity

18.2 Superconducting Excitation Gap

18.3 Problems with Landau's Order Parameter Concept

19 Conclusions

References

Index