siehe Modulhandbuch http://www.ph.tum.de/mh?mid=PH2030
Exercise to Applied Superconductivity 1: from Josephson Effects to RSFQ Logic (0000001099) S 2026
Literature
D. Kramer, Helium prices surge to record levels as shortage continues, Physics Today 76 (9), 18-20 (2023). W.P. Halperin, The impact of helium shortages on basic
The superconductor-insulator transition in two dimensions is a prototype continuous quantum phase transition at absolute zero, driven by a parameter other than temperature. Here we reveal this
| Michael Jurkutat, Carsten Kattinger, Stefan Tsankov, Richard Reznicek, Andreas Erb, Jürgen Haase
Mission statement
The Walther-Meißner-Institute for Low Temperature Research (WMI) is a research institute of the Bavarian Academy of Sciences and Humanities (BAdW). It conducts fundamental and
foundations of superconductivity (fluxoid quantization, critical currents, type-II behavior) development of improved helium liquefaction systems
We explore the physics at low and ultra-low temperatures with special focus on superconductivity and magnetism as well as on the control of quantum systems in the field of quantum technologies.
The Mott metal-insulator transition is one of the fundamental hallmarks of electronic correlations in a metal. Unconventional superconductivity and other fascinating phenomena often emerge in close
Brief description of the book "Festkörperphysik" The 1st edition of the book appeared in 2012 and was out of print already after 2 years. Therefore, a second revised and extended edition was
Applied Superconductivity
Lecture Notes AS Table of Contents.pdf AS Chapter 1.pdf
Superconductivity and Low Temperature Physics 1
SC+LTP-1 Introduction.pdf SC+LTP-1 Chapter1.pdf SC+LTP-1 Chapter2.pdf SC+LTP-1
Superconductivity and Low Temperature Physics 2
LTP2024 Introduction.pdf LTP2024 Chapter1.pdf LTP2024
Summer Semester 2024
Time: Thursday, 17.15 h Place: Lecture Hall 3, Department of Physics, James-Franck-Str. 1, D-85748 Garching
The properties of a large class of materials are determined by quantum effects. In such quantum materials, interesting novel phases emerge due to a subtle interplay between different microscopic
Transition metal oxides are of great interest due to their various physical properties (e.g. high temperature superconductivity, colossal magnetoresistance, ferroelectricity, nonlinear optical
Rudi Hackl was a member of the Gross group as a senior scientist between 2000 and 2021.
Rudi Hackl joined WMI already in 1988 as a postdoc and has been one of the key scientists in the field of
Prof. Dr. Dietrich Einzel was a member of the Andres and Gross group at WMI between 1983 and 2015. Since 2008, he has been a private lecturer, and in 2014, he was appointed Adjunct Professor for
Applied Superconductivity 1: from Josephson Effects to RSFQ Logic (0000001097) W 2017
Exercise to Applied Superconductivity 1: from Josephson Effects to RSFQ Logic (0000001099) S 2017
Exercise to Superconductivity and Low Temperature Physics 1 (0000003467) W 2011
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
see http://www.ph.tum.de/mh?mid=PH2032
- Grundwissen (supraleitende Materialien, Supraleiter im Magnetfeld, Typ-I und Typ-II Supraleiter, Thermodynamik)
- phänomenologische Beschreibung der Supraleitung (London- und Ginzburg-Landau
Superconductivity and Low Temperature Physics 2 (0000000356) S 2026
Superconductivity and Low Temperature Physics 1 (0000000020) S 2026
Superconductivity and Low Temperature Physics 2 (0000000356) S 2026
