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9781860942419

A Phase Transition Approach to High Temperature Superconductivity: Universal Properties of Cuprate Superconductors

by ;
  • ISBN13:

    9781860942419

  • ISBN10:

    1860942415

  • Format: Hardcover
  • Copyright: 2000-06-01
  • Publisher: WORLD SCIENTIFIC PUB CO INC
  • Purchase Benefits
List Price: $114.00
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Summary

The discovery of superconductivity at 30 K by Bednorz and Muller in 1986 ignited an explosion of interest in high temperature superconductivity. The initial development rapidly evolved into an intensive worldwide research effort -- which still persists after more than a decade -- to understand the phenomenon of cuprate superconductivity, to search for ways to raise the transition temperature and to produce materials which have the potential for technological applications.During the past decade of research on this subject, significant progress has been made on both the fundamental science and technological application fronts. A great deal of experimental data is now available on the cuprates, and various properties have been well characterized using high quality single crystals and thin films. Despite this enormous research effort, however, the underlying mechanisms responsible for superconductivity in the cuprates are still open to question.This book offers an understanding from the phase transition point of view, surveys and identifies thermal and quantum fluctuation effects, identifies material-independent universal properties and provides constraints for the microscopic description of the various phenomena. The text is presented in a format suitable for use in a graduate level course.

Table of Contents

Preface v
Introduction
1(36)
Cuprate superconductors
1(17)
Structure
2(1)
Doping
3(4)
Effective mass anisotropy and spatial dimensionality
7(3)
Pseudogap
10(3)
Symmetry of the order parameter
13(2)
Importance of critical fluctuations
15(3)
Universal critical properties of continuous phase transitions
18(14)
Static critical properties at finite temperature
18(5)
Dynamic critical properties at finite temperature
23(2)
Quantum critical properties
25(7)
Finite size effect and corrections to scaling
32(5)
Ginzburg - Landau phenomenology
37(36)
London phenomenology
37(9)
Ginzburg - Landau functional
46(2)
Mean-field treatment
48(11)
Meissner phase
49(2)
Length scales: London penetration depth and correlation length
51(4)
Classification of superconductors
55(2)
Upper critical field
57(2)
Flux quantization
59(2)
London model and first flux penetration field
61(3)
Effective mass anisotropy
64(9)
3D anisotropic London model
67(6)
Gaussian thermal fluctuations
73(26)
Gaussian fluctuations around the mean field solution
73(1)
Gaussian order parameter fluctuations
74(5)
Gaussian vector potential fluctuations
79(1)
Relevance of vector potential fluctuations
80(2)
Helicity modulus
82(3)
Effective mass anisotropy
85(3)
Fluctuation induced diamagnetism
88(11)
Isotropic system
88(6)
Effective mass anisotropy
94(2)
Magnetic torque
96(3)
Superfluidity and the n-vector model
99(26)
Ideal Bose gas
101(8)
Charged Bose gas subjected to a magnetic field
109(2)
Weakly interacting Bose gas
111(3)
Hydrodynamic approach
114(4)
The n-vector model
118(7)
Universality and scaling theory of classical critical phenomena at finite temperature
125(32)
Static critical phenomena in isotropic systems
125(11)
Superconductors with effective mass anisotropy
136(13)
Dimensional analysis
149(4)
Static critical properties
149(2)
Classical dynamic critical phenomena
151(2)
Implications of the universal critical amplitude relations
153(4)
Experimental evidence for classical critical behavior
157(76)
Critical behavior close to optimum doping
157(55)
Specific heat in zero field
157(12)
Temperature dependence of the penetration depth
169(2)
Corrections to scaling
171(4)
Temperature dependence of the diamagnetic susceptibility
175(1)
Scaling of the magnetization
175(2)
Crossing point phenomenon
177(4)
Magnetic torque and universal scaling function
181(8)
Magnetic field tuned phase transitions: Melting transition
189(5)
Magnetic field tuned phase transitions: Superconductor - normal conductor and insulator transitions
194(7)
Evidence for a Kosterlitz - Thouless - Berezinskii transition in thin films
201(5)
Temperature driven 2D to 3D crossover
206(6)
Doping dependence of the critical behavior
212(7)
Evidence for dynamic scaling
219(1)
Vortex glass to vortex fluid transition
220(4)
The (H,T) phase diagram of extreme type II superconductors emerging from Monte Carlo simulations
224(9)
Quantum Phase Transitions
233(40)
Scaling theory of quantum critical phenomena
233(9)
Quantum critical phenomena: conventional superconductors
242(6)
Quantum critical phenomena: cuprate superconductors
248(25)
Doping and disorder tuned superconductor to insulator transition
248(8)
Film thickness tuned superconductor to insulator transition
256(4)
Doping dependence of the chemical potential
260(1)
Magnetic field tuned transition
261(4)
Nature of the non-superconducting phase
265(3)
Superconductor to normal conductor transition
268(5)
Implications
273(36)
Interlayer tunneling model
273(3)
Symmetry of the order parameter
276(1)
Suppression of the transition temperature due to dimensional crossover and quantum fluctuations
277(3)
Pseudogap features
280(4)
Relationship between low frequency conductivity and zero temperature penetration depth
284(5)
Doping and pressure dependences of critical amplitudes
289(6)
Doping dependence of isotope and pressure coefficients
295(3)
Bose gas approach
298(1)
Effective pair mass
299(2)
Emerging phase diagrams
301(8)
A Mean field treatment 309(10)
Ising Model
309(6)
XY Model
315(4)
B XY model 319(18)
3D-2D Crossover in the XY model
319(13)
2D-XY model
320(4)
3D-XY model
324(3)
Layered XY model
327(4)
Anisotropic XY model
331(1)
Superconducting networks and films
332(5)
Models
332(3)
Uniform superconducting films
335(2)
Quantum phase transitions 337(14)
The harmonic oscillator
337(2)
Large-n limit of a model for distortive phase transitions
339(4)
Onset of superfluidity in the ideal Bose gas
343(1)
Superconductors
344(7)
D BCS theory 351(16)
Cooper instability
351(3)
Electron-phonon interaction
354(1)
Ground state in the BCS approximation
355(6)
Thermodynamic properties in the BCS - approximation
361(2)
Simple model
363(4)
E Superconducting properties of the attractive Hubbard model 367(44)
BCS --- BEC crossover
367(12)
BCS treatment of the attractive Hubbard model
379(9)
Phase diagram of the attractive Hubbard model on a lattice
388(12)
2D-XY behavior and KT transition in the attractive Hubbard model
400(11)
References 411(16)
Index 427

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