| Preface |
| Suggestions for Using This Book |
| Preface to the First Edition |
| Historical Overview / 1: |
| The Basic Phenomena / 1.1: |
| The London Equations / 1.2: |
| The Pippard Nonlocal Electrodynamics / 1.3: |
| The Energy Gap and the BCS Theory / 1.4: |
| The Ginzburg-Landau Theory / 1.5: |
| Type II Superconductors / 1.6: |
| Phase, Josephson Tunneling, and Fluxoid Quantization / 1.7: |
| Fluctuations and Nonequilibrium Effects / 1.8: |
| High-Temperature Superconductivity / 1.9: |
| Introduction to Electrodynamics of Superconductors / 2: |
| Screening of a Static Magnetic Field / 2.1: |
| Flat Slab in Parallel Magnetic Field / 2.2.1: |
| Critical Current of Wire / 2.2.2: |
| Type I Superconductors in Strong Magnetic Fields: The Intermediate State / 2.3: |
| Nonzero Demagnetizing Factor / 2.3.1: |
| Intermediate State in a Flat Slab / 2.3.2: |
| Intermediate State of a Sphere / 2.3.3: |
| Intermediate State above Critical Current of a Superconducting Wire / 2.4: |
| High-Frequency Electrodynamics / 2.5: |
| Complex Conductivity in Two-Fluid Approximation / 2.5.1: |
| High-Frequency Dissipation in Superconductors / 2.5.2: |
| The BCS Theory / 3: |
| Cooper Pairs / 3.1: |
| Origin of the Attractive Interaction / 3.2: |
| The BCS Ground State / 3.3: |
| Variational Method / 3.4: |
| Determination of the Coefficients / 3.4.1: |
| Evaluation of Ground-State Energy / 3.4.2: |
| Isotope Effect / 3.4.3: |
| Solution by Canonical Transformation / 3.5: |
| Excitation Energies and the Energy Gap / 3.5.1: |
| Finite Temperatures / 3.6: |
| Determination of T[subscript c] / 3.6.1: |
| Temperature Dependence of the Gap / 3.6.2: |
| Thermodynamic Quantities / 3.6.3: |
| State Functions and the Density of States / 3.7: |
| Density of States / 3.7.1: |
| Electron Tunneling / 3.8: |
| The Semiconductor Model / 3.8.1: |
| Normal-Normal Tunneling / 3.8.2: |
| Normal-Superconductor Tunneling / 3.8.3: |
| Superconductor-Superconductor Tunneling / 3.8.4: |
| Phonon Structure / 3.8.5: |
| Transition Probabilities and Coherence Effects / 3.9: |
| Ultrasonic Attenuation / 3.9.1: |
| Nuclear Relaxation / 3.9.2: |
| Electromagnetic Absorption / 3.9.3: |
| Electrodynamics / 3.10: |
| Calculation of K(0, T) or [lambda subscript L](T) / 3.10.1: |
| Calculation of K(q, 0) / 3.10.2: |
| Nonlocal Electrodynamics in Coordinate Space / 3.10.3: |
| Effect of Impurities / 3.10.4: |
| Complex Conductivity / 3.10.5: |
| The Penetration Depth / 3.11: |
| Preliminary Estimate of [lambda] for Nonlocal Case / 3.11.1: |
| Solution by Fourier Analysis / 3.11.2: |
| Temperature Dependence of [lambda] / 3.11.3: |
| Penetration Depth in Thin Films: [lambda subscript eff] and [lambda subscript perpendicular, bottom] / 3.11.4: |
| Measurement of [lambda] / 3.11.5: |
| Concluding Summary / 3.12: |
| Ginzburg-Landau Theory / 4: |
| The Ginzburg-Landau Free Energy / 4.1: |
| The Ginzburg-Landau Differential Equations / 4.2: |
| The Ginzburg-Landau Coherence Length / 4.2.1: |
| Calculations of the Domain-Wall Energy Parameter / 4.3: |
| Critical Current of a Thin Wire or Film / 4.4: |
| Fluxoid Quantization and the Little-Parks Experiment / 4.5: |
| The Fluxoid / 4.5.1: |
| The Little-Parks Experiment / 4.5.2: |
| Parallel Critical Field of Thin Flims / 4.6: |
| Thicker Films / 4.6.1: |
| The Linearized GL Equation / 4.7: |
| Nucleation in Bulk Samples: H[subscript c2] / 4.8: |
| Nucleation at Surfaces: H[subscript c3] / 4.9: |
| Nucleation in Films and Foils / 4.10: |
| Angular Dependence of the Critical Field of Thin Films / 4.10.1: |
| Nucleation in Films of Intermediate Thickness / 4.10.2: |
| The Abrikosov Vortex State at H[subscript c2] / 4.11: |
| Magnetic Properties of Classic Type II Superconductors / 5: |
| Behavior Near H[subscript c1]: The Structure of an Isolated Vortex / 5.1: |
| The High-[kappa] Approximation / 5.1.1: |
| Vortex-Line Energy / 5.1.2: |
| Interaction between Vortex Lines / 5.2: |
| Magnetization Curves / 5.3: |
| Low Flux Density / 5.3.1: |
| Intermediate Flux Densities / 5.3.2: |
| Regime Near H[subscript c2] / 5.3.3: |
| Flux Pinning, Creep, and Flow / 5.4: |
| Flux Flow / 5.5: |
| The Bardeen-Stephen Model / 5.5.1: |
| Onset of Resistance in a Wire / 5.5.2: |
| Experimental Verification of Flux Flow / 5.5.3: |
| Concluding Remarks on Flux Flow / 5.5.4: |
| The Critical-State Model / 5.6: |
| Thermally Activated Flux Creep / 5.7: |
| Anderson-Kim Flux-Creep Theory / 5.7.1: |
| Thermal Instability / 5.7.2: |
| Superconducting Magnets for Time-Varying Fields / 5.8: |
| Flux Jumps / 5.8.1: |
| Twisted Composite Conductors / 5.8.2: |
| Josephson Effect I: Basic Phenomena and Applications / 6: |
| Introduction / 6.1: |
| The Josephson Critical Current / 6.2: |
| Short One-Dimensional Metallic Weak Links / 6.2.1: |
| Other Weak Links / 6.2.2: |
| Gauge-Invariant Phase / 6.2.3: |
| The RCSJ Model / 6.3: |
| Definition of the Model / 6.3.1: |
| I-V Characteristics at T=0 / 6.3.2: |
| Effects of Thermal Fluctuations / 6.3.3: |
| rf-Driven Junctions / 6.3.4: |
| Josephson Effect in Presence of Magnetic Flux / 6.4: |
| The Basic Principle of Quantum Interference / 6.4.1: |
| Extended Junctions / 6.4.2: |
| Time-Dependent Solutions / 6.4.3: |
| SQUID Devices / 6.5: |
| The dc SQUID / 6.5.1: |
| The rf SQUID / 6.5.2: |
| SQUID Applications / 6.5.3: |
| Arrays of Josephson Junctions / 6.6: |
| Arrays in Zero Magnetic Field / 6.6.1: |
| Arrays in Uniform Magnetic Field / 6.6.2: |
| Arrays in rf Fields: Giant Shapiro Steps / 6.6.3: |
| S-I-S Detectors and Mixers / 6.7: |
| S-I-S Detectors / 6.7.1: |
| S-I-S Mixers / 6.7.2: |
| Josephson Effect II: Phenomena Unique to Small Junctions / 7: |
| Damping Effect of Lead Impedance / 7.1: |
| Effect on Retrapping Current / 7.2.1: |
| The Phase Diffusion Branch / 7.2.2: |
| Quantum Consequences of Small Capacitance / 7.3: |
| Particle Number Eigenstates / 7.3.1: |
| Macroscopic Quantum Tunneling / 7.3.2: |
| Introduction to Single Electron Tunneling: The Coulomb Blockade and Staircase / 7.4: |
| Energy and Charging Relations in Quasi-Equilibrium / 7.5: |
| Zero Bias Circuit with Normal Island / 7.5.1: |
| Even-Odd Number Parity Effect with Superconducting Island / 7.5.2: |
| Zero Bias Supercurrents with Superconducting Island and Leads / 7.5.3: |
| Double-Junction Circuit with Finite Bias Voltage / 7.6: |
| Orthodox Theory and Determination of the I-V Curve / 7.6.1: |
| The Special Case R[subscript 2] [double greater-than sign] R[subscript 1] / 7.6.2: |
| Cotunneling or Macroscopic Quantum Tunneling of Charge / 7.6.3: |
| Superconducting Island with Finite Bias Voltage / 7.6.4: |
| Fluctuation Effects in Classic Superconductors / 8: |
| Appearance of Resistance in a Thin Superconducting Wire / 8.1: |
| Appearance of Resistance in a Thin Superconducting Film: The Kosterlitz-Thouless Transition / 8.2: |
| Superconductivity above T[subscript c] in Zero-Dimensional Systems / 8.3: |
| Spatial Variation of Fluctuations / 8.4: |
| Fluctuation Diamagnetism above T[subscript c] / 8.5: |
| Diamagnetism in Two-Dimensional Systems / 8.5.1: |
| Time Dependence of Fluctuations / 8.6: |
| Fluctuation-Enhanced Conductivity above T[subscript c] / 8.7: |
| Three Dimensions / 8.7.1: |
| Two Dimensions / 8.7.2: |
| One Dimension / 8.7.3: |
| Anomalous Contributions to Fluctuation Conductivity / 8.7.4: |
| High-Frequency Conductivity / 8.7.5: |
| The High-Temperature Superconductors / 9: |
| The Lawrence-Doniach Model / 9.1: |
| The Anisotropic Ginzburg-Landau Limit / 9.2.1: |
| Crossover to Two-Dimensional Behavior / 9.2.2: |
| Discussion / 9.2.3: |
| Magnetization of Layered Superconductors / 9.3: |
| The Anisotropic Ginzburg-Landau Regime / 9.3.1: |
| The Lock-In Transition / 9.3.2: |
| Flux Motion and the Resistive Transition: An Initial Overview / 9.4: |
| The Melting Transition / 9.5: |
| A Simple Model Calculation / 9.5.1: |
| Experimental Evidence / 9.5.2: |
| Two-Dimensional vs. Three-Dimensional Melting / 9.5.3: |
| The Effect of Pinning / 9.6: |
| Pinning Mechanisms in HTSC / 9.6.1: |
| Larkin-Ovchinnikov Theory of Collective Pinning / 9.6.2: |
| Giant Flux Creep in the Collective Pinning Model / 9.6.3: |
| The Vortex-Glass Model / 9.6.4: |
| Correlated Disorder and the Boson Glass Model / 9.6.5: |
| Granular High-Temperature Superconductors / 9.7: |
| Effective Medium Parameters / 9.7.1: |
| Relationship between Granular and Continuum Models / 9.7.2: |
| The "Brick-Wall" Model / 9.7.3: |
| Fluxons and High-Frequency Losses / 9.8: |
| Anomalous Properties of High-Temperature and Exotic Superconductors / 9.9: |
| Unconventional Pairing / 9.9.1: |
| Pairing Symmetry and Flux Quantization / 9.9.2: |
| The Energy Gap / 9.9.3: |
| Heavy Fermion Superconductors / 9.9.4: |
| Special Topics / 10: |
| The Bogoliubov Method: Generalized Self-Consistent Field / 10.1: |
| Dirty Superconductors / 10.1.1: |
| Uniform Current in Pure Superconductors / 10.1.2: |
| Excitations in Vortex / 10.1.3: |
| Magnetic Perturbations and Gapless Superconductivity / 10.2: |
| Depression of T[subscript c] by Magnetic Perturbations / 10.2.1: |
| Time-Dependent Ginzburg-Landau Theory / 10.2.2: |
| Electron-Phonon Relaxation / 10.3.1: |
| Nonequilibrium Superconductivity / 11: |
| Quasi-Particle Disequilibrium / 11.1: |
| Energy-Mode vs. Charge-Mode Disequilibrium / 11.2.1: |
| Relaxation Times / 11.2.2: |
| Energy-Mode Disequilibrium: Steady-State Enhancement of Superconductivity / 11.3: |
| Enhancement by Microwaves / 11.3.1: |
| Enhancement by Extraction of Quasi-Particles / 11.3.2: |
| Energy-Mode Disequilibrium: Dynamic Nonequilibrium Effects / 11.4: |
| GL Equation for Time-Dependent Gap / 11.4.1: |
| Transient Superconductivity above I[subscript c] / 11.4.2: |
| Dynamic Enhancement in Metallic Weak Links / 11.4.3: |
| Charge-Mode Disequilibrium: Steady-State Regimes / 11.5: |
| Andreev Reflection / 11.5.1: |
| Subharmonic Energy Gap Structure / 11.5.2: |
| Time-Dependent Charge-Mode Disequilibrium: Phase-Slip Centers / 11.6: |
| Units / Appendix 1: |
| Notation and Conventions / Appendix 2: |
| Exact Solution for Penetration Depth by Fourier Analysis / Appendix 3: |
| Bibliography |
| Index |
図書
