Digital Teaching
The lecture is held as a combined digital and face-to-face course. During the semester, regular lecture dates will take place in Zoom. At the end of the semester, a practical demonstration of high-temperature superconductors as well as the detailed possibility of Q&A will be given on 2 presence dates to be agreed upon. Individual face-to-face oral exams will conclude the lecture.
[url]http://tu-darmstadt.zoom-x.de/j/67652005939[/url]
Course Contents
[list]
[*]Basics and modelling of electrical conductivity at DC and RF
[*]Kamerligh-Onnes experiment, Meissner effect, London equations
[*]Superconductor state diagram (phase diagram)
[*]Introduction to Ginzburg-Landau theory (if necessary also: introduction to basic quantum mechanics)
[*]Typ I / II Superconductor, Flux quantization, Flux vortices
[*]Superconducting cables
[*]Superconductor magnetization, Hysteresis, Bean‘s model
[*]Cooper pairs (briefly: findings of the BCS theory)
[*]AC superconductivity, two fluid model, RF cavities
[*]Cooper pair tunneling, Josephson junctions, SQUIDs
[*]Applications: Magnets in accelerator and medical technology, precision field and current measurements, superconducting motors, generators, and transformers
[*]Experimental demonstration of high temperature superconductors
[/list]
Literature
[list]
[*]W. Buckel, R. Kleiner: „Supraleitung Grundlagen und Anwendungen“; Wiley VCH, 7. Auflage 2013.
[*]R.G. Sharma; „Superconductivity, Basics and Applications to Magnets“; Springer International Publishing, 2015 (online available).
[*]H. Padamsee: „RF-Superconductivity“; Wiley VCH Weinheim, 2009.
[*]P. Seidel (Ed.), „Applied Superconductivity“, Wiley VCH Weinheim, 2015.
[/list]
Preconditions
Electrodynamics (Maxwell’s equations)
Online Offerings
Moodle
The lecture is held as a combined digital and face-to-face course. During the semester, regular lecture dates will take place in Zoom. At the end of the semester, a practical demonstration of high-temperature superconductors as well as the detailed possibility of Q&A will be given on 2 presence dates to be agreed upon. Individual face-to-face oral exams will conclude the lecture.
[url]http://tu-darmstadt.zoom-x.de/j/67652005939[/url]
Course Contents
[list]
[*]Basics and modelling of electrical conductivity at DC and RF
[*]Kamerligh-Onnes experiment, Meissner effect, London equations
[*]Superconductor state diagram (phase diagram)
[*]Introduction to Ginzburg-Landau theory (if necessary also: introduction to basic quantum mechanics)
[*]Typ I / II Superconductor, Flux quantization, Flux vortices
[*]Superconducting cables
[*]Superconductor magnetization, Hysteresis, Bean‘s model
[*]Cooper pairs (briefly: findings of the BCS theory)
[*]AC superconductivity, two fluid model, RF cavities
[*]Cooper pair tunneling, Josephson junctions, SQUIDs
[*]Applications: Magnets in accelerator and medical technology, precision field and current measurements, superconducting motors, generators, and transformers
[*]Experimental demonstration of high temperature superconductors
[/list]
Literature
[list]
[*]W. Buckel, R. Kleiner: „Supraleitung Grundlagen und Anwendungen“; Wiley VCH, 7. Auflage 2013.
[*]R.G. Sharma; „Superconductivity, Basics and Applications to Magnets“; Springer International Publishing, 2015 (online available).
[*]H. Padamsee: „RF-Superconductivity“; Wiley VCH Weinheim, 2009.
[*]P. Seidel (Ed.), „Applied Superconductivity“, Wiley VCH Weinheim, 2015.
[/list]
Preconditions
Electrodynamics (Maxwell’s equations)
Online Offerings
Moodle
- Lehrende: NiedermayerUwe
Semester: ST 2024