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Table of Contents
Intro
Preface
Acknowledgements
Author biographies
Mark Ainslie
Hiroyuki Fujishiro
Chapter 1 Fundamentals of bulk superconducting materials
1.1 Bulk superconductors
1.2 Magnetic properties of bulk superconductors
1.2.1 Superconducting material classifications
1.2.2 Flux pinning and trapping
1.2.3 Flux creep
1.3 Fabrication processes
1.3.1 Bulk (RE)BCO superconductors
1.3.2 Bulk MgB2 superconductors
1.3.3 Bulk iron-pnictide superconductors
1.4 Magnetisation of bulk superconductors
1.4.1 Pulsed field magnetisation
1.5 Bulk superconductor applications
1.5.1 Flux pinning applications
1.5.2 Flux trapping applications
1.5.3 Flux shielding applications
1.5.4 Magnetic lens
1.5.5 Conductor alternative
References
Chapter 2 Numerical modelling of bulk superconducting materials
2.1 Modelling of bulk superconductors
2.1.1 Analytical techniques
2.1.2 Numerical techniques
2.2 Finite element method (FEM)
2.2.1 Modelling bulk superconductors using FEM
References
Chapter 3 Modelling magnetisation of bulk superconductors
3.1 Magnetisation of bulk superconductors
3.1.1 Zero-field-cooled (ZFC) and field-cooled (FC) magnetisation
3.1.2 Pulsed field magnetisation (PFM)
References
Chapter 4 Demagnetisation and novel, hybrid superconductor structures
4.1 Demagnetisation effects and AC losses
4.2 Novel and hybrid bulk superconductor structures
4.2.1 Composite structures with improved thermal conductivity
4.2.2 Hybrid ferromagnet-superconductor structures
4.2.3 Hollow bulk cylinders and tubes for shielding
4.2.4 Hybrid trapped field magnet lens
References
Chapter
A.1 Introduction
A.2 Experimental procedure
A.2.1 Thermal conductivity
A.2.2 Thermal dilatation
A.3 Typical results
A.3.1 Bulk (RE)BCO
A.3.2 Bulk MgB2.
Further reading.
Preface
Acknowledgements
Author biographies
Mark Ainslie
Hiroyuki Fujishiro
Chapter 1 Fundamentals of bulk superconducting materials
1.1 Bulk superconductors
1.2 Magnetic properties of bulk superconductors
1.2.1 Superconducting material classifications
1.2.2 Flux pinning and trapping
1.2.3 Flux creep
1.3 Fabrication processes
1.3.1 Bulk (RE)BCO superconductors
1.3.2 Bulk MgB2 superconductors
1.3.3 Bulk iron-pnictide superconductors
1.4 Magnetisation of bulk superconductors
1.4.1 Pulsed field magnetisation
1.5 Bulk superconductor applications
1.5.1 Flux pinning applications
1.5.2 Flux trapping applications
1.5.3 Flux shielding applications
1.5.4 Magnetic lens
1.5.5 Conductor alternative
References
Chapter 2 Numerical modelling of bulk superconducting materials
2.1 Modelling of bulk superconductors
2.1.1 Analytical techniques
2.1.2 Numerical techniques
2.2 Finite element method (FEM)
2.2.1 Modelling bulk superconductors using FEM
References
Chapter 3 Modelling magnetisation of bulk superconductors
3.1 Magnetisation of bulk superconductors
3.1.1 Zero-field-cooled (ZFC) and field-cooled (FC) magnetisation
3.1.2 Pulsed field magnetisation (PFM)
References
Chapter 4 Demagnetisation and novel, hybrid superconductor structures
4.1 Demagnetisation effects and AC losses
4.2 Novel and hybrid bulk superconductor structures
4.2.1 Composite structures with improved thermal conductivity
4.2.2 Hybrid ferromagnet-superconductor structures
4.2.3 Hollow bulk cylinders and tubes for shielding
4.2.4 Hybrid trapped field magnet lens
References
Chapter
A.1 Introduction
A.2 Experimental procedure
A.2.1 Thermal conductivity
A.2.2 Thermal dilatation
A.3 Typical results
A.3.1 Bulk (RE)BCO
A.3.2 Bulk MgB2.
Further reading.