Useful Links
Physics
Condensed Matter and Materials Physics
Solid State Physics
1. Introduction to Solid State Physics
2. Crystal Structure and Geometry
3. Diffraction and Reciprocal Lattice
4. Crystal Binding and Elastic Properties
5. Lattice Dynamics and Phonons
6. Thermal Properties
7. Free Electron Theory
8. Band Theory of Solids
9. Semiconductor Physics
10. Optical Properties
11. Magnetic Properties
12. Superconductivity
13. Defects in Crystals
Superconductivity
Phenomenological Properties
Zero Electrical Resistance
Critical Temperature
Isotope Effect
Meissner Effect
Perfect Diamagnetism
Flux Expulsion
Critical Magnetic Field
Thermodynamic Properties
Specific Heat Jump
Entropy Difference
Free Energy
London Theory
London Equations
Local Electrodynamics
Penetration Depth
Flux Quantization
Macroscopic Quantum Coherence
Flux Quantum
Ginzburg-Landau Theory
Order Parameter
Free Energy Functional
Coherence Length
Type I and Type II Superconductors
Ginzburg-Landau Parameter
Critical Fields
Mixed State
Microscopic BCS Theory
Cooper Pair Formation
Electron-Phonon Interaction
Instability of Fermi Sea
BCS Ground State
Coherent Superposition
Energy Gap
Quasiparticle Excitations
Bogoliubov Transformation
Density of States
Thermodynamic Properties
Specific Heat
Critical Field
Isotope Effect
Josephson Effects
Josephson Junctions
Weak Links
Tunneling Hamiltonian
DC Josephson Effect
Supercurrent
Current-Phase Relation
AC Josephson Effect
Voltage-Frequency Relation
Shapiro Steps
Applications
SQUIDs
Josephson Voltage Standards
Unconventional Superconductors
High-Temperature Superconductors
Cuprate Structure
d-wave Pairing
Phase Diagram
Heavy Fermion Superconductors
Organic Superconductors
Iron-Based Superconductors
Previous
11. Magnetic Properties
Go to top
Next
13. Defects in Crystals