The Theory of Magnetism Made... | Buy

The original edition of The Theory of Magnetism was the first book to develop the various relevant topics using modern methods adapted for the many-body problem and thus it became popular (reportedly the "most-stolen" book from the exhibition stalls at the March meeting of the American Physical Society!). It presented and taught the fermionic field theory central to Onsager's analysis of the statistical mechanics of the two-dimensional Ising model of magnetism. In its pages the Lieb-Mattis theorems on magnetic ordering of electronic energy levels and on the absence of ferromagnetism in one dimension were restated and proved in a form accessible to students. The exchange mechanism in insulators and the Ruderman-Kittel interaction in metals were some of the innovative topics presented to the reader. Spin waves and their interactions were analyzed in some detail. The first chapter, on the history of physics as seen through the prism of research in magnetism, co-authored with Dr Noemi Mattis, proved especially popular. In this new edition, while retaining much of the material in earlier editions, especially the first chapter, the author has eliminated some of the bulk (the most recent edition was in two volumes) and added a number of new subjects. Among these are the effects of lowering the dimensionality (exact solutions of some important models in zero and one dimension are exhibited and contrasted with the three-dimensional versions) and the importance of the two-body Coulomb interactions. The reader is introduced to the topic of critical exponents, which has been so marvellously worked out in recent decades. Quoting a novel theorem by Lieb and exotic band structures, the authorre-examines the origins of ferromagnetism. In the presentation, physical principles come first, the mathematics second. Developing the reader's intuition and mastery of the subject takes precedence. Because of this the book was not

Daniel C. Mattis, B.S., M.S., Ph.D., Fellow of the American Physical Society (APS), is a frequent lecturer at research institutions

Prologue

Chapter 1. History of Magnetism

1

(52)

1.1. Physics and Metaphysics

3

(3)

1.2. Gilbert and Descartes

6

(6)

1.3. Rise of Modern Science

12

(4)

1.4. Electrodynamics

16

(7)

1.5. The Electron

23

(3)

1.6. The Demise of Classical Physics

26

(5)

1.7. Quantum Theory

31

(4)

1.8. Modern Foundations

35

(4)

1.9. Magnetic Bubbles

39

(5)

1.10. Ultimate Thin Films

44

(3)

1.11. Dilute Magnetic Alloys

47

(2)

1.12. New Directions

49

(4)

Chapter 2. Currents or Spins?

53

(17)

2.1. Charge Currents or Spins?

53

(3)

2.2. The Magnetic Dipole

56

(1)

2.3. The Magnetic Dipole-Dipole Interactions

57

(6)

2.4. The Exchange Interactions

63

(2)

2.5. Metals and Their Alloys

65

(3)

2.6. Superconductivity

68

(1)

2.7. The Need to Study Spin Angular Momentum

69

(1)

Chapter 3. Quantum Theory of Angular Momentum

70

(34)

3.1. Kinetic Angular Momentum

70

(4)

3.2. Spherical Harmonics

74

(4)

3.3. Reason for Integer / and m

78

(2)

3.4. Matrices of Angular Momentum

80

(2)

3.5. Pauli Spin Matrices

82

(1)

3.6. Compounding Angular Momentum

83

(4)

3.7. Equations of Motion of Interacting Angular Momenta

87

(1)

3.8. Coupled Boson Representation

87

(3)

3.9. Rotations

90

(2)

3.10. More on Compound Angular Momentum

92

(3)

3.11. Other Representations

95

(1)

3.12. Spins One-Half: Special Tricks

96

(2)

3.13. Spins One

98

(2)

3.14. Quadratic Forms

100

(1)

3.15. Projection Operators

101

(3)

Chapter 4. Magnetism and the Many-Body Problem

104

(71)

4.1. Hamiltonian Physics and Degeneracy

104

(3)

4.2. The Pauli Principle

107

(4)

4.3. The Two-Fermion Problem

111

(2)

4.4. Electrons in One Dimension: A Theorem

113

(3)

4.5. The Wronskian

116

(2)

4.6. States of Three Electrons

118

(2)

4.7. Eigenfunctions of Total S² and Sz

120

(5)

4.8. Hund's Rules

125

(2)

4.9. p³ Configuration

127

(6)

4.10. p² and p4 Configurations

133

(6)

4.11. Second Quantization

139

(4)

4.12. Double Exchange

143

(3)

4.13. Superexchange

146

(3)

4.14. Jellium

149

(5)

4.15. Hubbard Model: An Introduction

154

(9)

4.16. Nagaoka's Ferromagnetism

163

(4)

4.17. One Dimension: Exact Solutions

167

(1)

4.18. Ferrimagnetism

168

(4)

4.19. Spin-Dependent Tunneling

172

(3)

Chapter 5. From Magnons to Solitons: Spin Dynamics

175

(82)

5.1. Spin Waves as Harmonic Oscillators

176

(9)

5.2. One-Magnon Eigenstates in Ferromagnets

185

(1)

5.3. Two-Magnon States and Eigenstates in Ferromagnets

186

(9)

5.4. Bound States in One Dimension

195

(1)

5.5. Bound States in Two and Three Dimensions

196

(4)

5.6. Antiferromagnetic Magnons: The One-Dimensional XY Model

200

(6)

5.7. Bethe's Solution of One-Dimensional Heisenberg Antiferromagnet

206

(9)

5.8. Linearized Antiferromagnetic Magnons

215

(9)

5.9. Ferrimagnetism

224

(2)

5.10. Some Rigorous Notions in Antiferro- and Ferri-Magnetism

226

(2)

5.11. Vortices

228

(3)

5.12. Solitons and Bloch Domain Walls: Introductory Material

231

(4)

5.13. Solitary Wave Solution

235

(6)

5.14. More on Magnetic Domains

241

(1)

5.15. Time-Dependent Phenomena

242

(5)

5.16. Majumdar-Ghosh Model and "Quantum Frustration"

247

(3)

5.17. Integer Spins

250

(4)

5.18. The AKLT Spin One Chain

254

(1)

5.19. Defective Antiferromagnets

255

(2)

Chapter 6. Magnetism in Metals

257

(87)

6.1. Bloch and Wannier States

259

(1)

6.2. Tight-Binding

260

(7)

6.3. Weak Magnetic Properties

267

(6)

6.4. Exchange in Solids: Construction of a Model Hamiltonian

273

(8)

6.5. Perturbation-Theoretic Derivation of Heisenberg Hamiltonian

281

(3)

6.6. Heisenberg Hamiltonian in Metals

284

(3)

6.7. Ordered Magnetic Metals: Deriving the Ground State

287

(9)

6.8. Kondo Effect

296

(8)

6.9. Spin Glasses

304

(6)

6.10. Magnetism without Localized Spins: Preliminaries

310

(4)

6.11. Degenerate Bands and Intra-Atomic Exchange Forces

314

(6)

6.12. Magnons in Metals

320

(7)

6.13. Marginal Magnetism of Impurities

327

(10)

6.14. Correlations and Equivalence to s-d Model

337

(5)

6.15. Periodic Anderson Model

342

(2)

Chapter 7. Statistical Thermodynamics

344

(94)

7.1. Spins in a Magnetic Field

344

(5)

7.2. The Partition Function

349

(5)

7.3. The Concept of the Molecular Field

354

(4)

7.4. Discontinuity in Specific Heat

358

(3)

7.5. Magnetic Susceptibility and Spontaneous Magnetization

361

(4)

7.6. Adiabatic Demagnetization

365

(1)

7.7. Antiferromagnetism

366

(3)

7.8. Short-Ranged versus Long-Ranged Interactions

369

(6)

7.9. Fermions, Bosons, and all that

375

(3)

Fermions

375

(1)

Bosons

375

(1)

Gaussian

376

(1)

Legendre Transformations

377

(1)

7.10. Gaussian and Spherical Models

378

(11)

Gaussian Model

379

(3)

Spherical Model

382

(5)

Watson's Integrals Generalized

387

(2)

7.11. Magnetic Susceptibility in Gaussian and Spherical Models

389

(3)

7.12. Spherical Antiferromagnet

392

(3)

7.13. Spherical Model Spin Glass

395

(12)

Magnetic Properties of Spin Glass

399

(8)

7.14. Thermodynamics of Magnons

407

(7)

7.15. Magnetism in Two Dimensions

414

(4)

7.16. The XY Model: 1D

418

(8)

7.17. The XY Model: 2D

426

(7)

7.18. Transfer Matrix of Plane Rotator Model

433

(5)

Chapter 8. The Ising Model

438

(95)

8.1. High Temperature Expansions

441

(4)

8.2. Graph Theory

445

(3)

8.3. Low Temperature Expansions and the Duality Relations

448

(4)

8.4. Peierls' Proof of Long Range Order

452

(2)

8.5. 1D Ising Model in Longitudinal Fields

454

(8)

8.6. 1D Ising Model in Transverse Fields

462

(12)

8.7. Concerning Quadratic Forms of Fermion Operators

474

(4)

8.8. Two-Dimensional Ising Model: The Transfer Matrix

478

(7)

8.9. Solution of Two-Dimensional Ising Model in Zero Field

485

(9)

8.10. Spontaneous Magnetization and Magnetic Susceptibility

494

(8)

8.11. Zeros of the Partition Function

502

(5)

8.12. Miscellania, Including 2D Antiferromagnets

507

(10)

8.13. The Three-Dimensional Ising Model

517

(9)

8.14. Ising Gauge Glass

526

(2)

8.15. Frustration

528

(5)

Chapter 9. Miscellaneous Advanced Topics

533

(16)

9.1. Critical Phenomena

533

(3)

9.2. Green Functions Formalism

536

(3)

9.3. Nonlinear Responses and Chaos

539

(1)

9.4. Kondo Phenomenon: The s-d Model Redux

539

(8)

9.5. Scaling, Renormalization and Information Theory

547

(2)

Bibliography

549

(12)

Index

561

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