| Allgemeine Angaben |
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| Exercise to Theoretical Solid State Physics | | |
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| Angaben zur Abhaltung |
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I) Symmetries and structure of condensed matter
Phases and broken symmetries
Determination of structure by x-ray diffraction
II) Lattice vibrations
Phonons and thermodynamics
Neutron scattering, dynamic structure factor
Anharmonic effects, melting, Lindemann criterion
III) Electrons
Bonding types, stability
Bloch theorem, Wannier functions, band theory
Fermi surfaces, Thermodynamics
Semiclassical dynamics of electrons, Bloch oscillations
Edge state theory of the quantum Hall effect
IV) Many particle effects and disorder
Interacting electron gas, screening, Wigner lattice
Density Functional Theory
Electron-Phonon interaction, BCS-theory of superconductivity
Anderson localization in disordered quantum systems |
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Successful participation provides the following skills:
Mathematical formulation of relevant structures of matter and their atomic composition. Calculation of the structural and dynamic properties of matter in terms of simple models
Explain the physics of structural phase transitions at surfaces and for defect structures
Understand modern methods for calculating the electronic structure of solids. Ability to perform simple density functional calculations
Approximations and methods for solving many particle problems in condensed matter physics
Understand and explain the nature of correlated low-dimensional systems in the framework of Fermi- or Luttinger liquid theory
Explain and theoretically describe electronic phase transitions such as superconductivity |
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| Für die Anmeldung zur Teilnahme müssen Sie sich in TUMonline als Studierende*r identifizieren. |
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| Zusatzinformationen |
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N.W. Ashcroft and N.D. Mermin, Solid State Physics
P.M. Chaikin and T.C. Lubensky, Principles of Condensed Matter Physics |
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