E-raamat: Physics of Critical Fluctuations

1. Classical Approach.- 1.1 Introduction.- 1.2 Landau Theory.- 1.3
Broken Symmetry and Condensation.- 1.4 Ergodicity.- 1.5 Gaussian
Approximation.- 1.6 The Ginzburg Criterion.- 1.7 The Scaling Hypothesis.- 2
The Ginzburg-Landau Functional.- 2.1 Introduction.- 2.2 Classical Systems.-
2.3 Quantum Systems.- 3 Wilsons Renormalization Scheme.- 3.1 Introduction.-
3.2 Kadanoffs Invariance.- 3.3 Wilsons Theory.- 4 Field Theoretical RG.-
4.1 Introduction.- 4.2 Perturbation Theory.- 4.3 Renormalization.- 4.4
Scaling Laws.- 4.5 ?-Expansion.- 4.6 Expansions at d = 3.- 4.7 Results of
Different Approaches.- 5 Generalized RG Approach.- 5.1 Introduction.- 5.2
Scale Transformations.- 5.3 Scale Equations.- 5.4 RG Equations.- 5.5
Applications of Generalized SE.- 5.6 ?-Expansion.- 5.7 Comparison of
Different RG Approaches.- 6 RG Study of Particular Systems.- 6.1 Reduction of
the Characteristic Set.- 6.2 The Gaussian Model.- 6.3 The Ų4 Model.- 6.4 The
Ų4+Ų6-Model.- 6.5 Free Energy in the Critical Region.- 7 Competing
Interactions.- 7.1 Heisenberg Magnets.- 7.2 Bicritical Points in
Antiferromagnets.- 7.3 Dipole Interaction.- 7.4 Impure Systems.- 8 Exactly
Solvable Models and RG.- 8.1 Fluctuation Effects in Spherical Model.- 8.2
Inversion of Phase Transitions.- 8.3 Model with Reduced Interaction.- 8.4
First-Order Transitions.- 8.5 RG and Reduced Interactions.- 9 Application to
Copper Oxides.- 9.1 Introduction.- 9.2 La2CuO4 Systems.- 9.3 Oxygen Ordering
in ABa2Cu3O6+x.- 9.4 d-Pairing in the Superconducting State.- A Evaluation of
Integrals.- A.1 Gaussian Integral.- A.2 A Typical Diagram.- B Local RG.- B.1
General Consideration.- B.2 Spectral Theorems.