Electron-phonon interactions and Kohn anomalies: Difference between revisions
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<math>H^0_{ph} = \sum_{k \lambda}\omega_{k \lambda} a^\dagger_{k \lambda} + \frac{1}{2}</math> | <math>H^0_{ph} = \sum_{k \lambda}\omega_{k \lambda} a^\dagger_{k \lambda} + \frac{1}{2}</math> | ||
<math>H^0_{coul} = \frac{1}{2} \sum_{k k^\prime q \atop \sigma \sigma^{\prime} } V(q)c^\dagger_{k ^\prime + q \sigma^\prime }c^\dagger_{k \sigma} | <math>H^0_{coul} = \frac{1}{2} \sum_{k k^\prime q \atop \sigma \sigma^{\prime} } V(q)c^\dagger_{k ^\prime + q \sigma^\prime } c^\dagger_{k \sigma} c_{k+q \sigma} c_{k^{\prime} \sigma^{\prime}} | ||
</math> | </math> | ||
Revision as of 17:49, 12 December 2012
Electron-phonon interactions
The study of interactions between electrons and phonons, is an interesting and classical topic in quantum many body theory as well as condensed matter physics. The electron-phonon interaction leads to many novel properties in metals, for instance, electrical resistance, thermal resistance, superconductivity and the renormalization of linear electronic specific heat. [1]
Free electrons in lattice
In contrary to the independent electron model, where In the tight-binding approximation,
Phonons: crystal vibrations
Lattice Vibration and Phonons in 1D
Acoustical and Optical Phonon in 3D
Derivation of Hamiltonian Electron-Phonon Coupling
The Hamiltonian for the electron-phonon interaction can be described as
Where
