Electron-phonon interactions and Kohn anomalies

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 electrons experience weak periodic potential, the interaction of an electron with all other electrons and nuclei is represented by ‘effective potential’ in some average way, in the tight-binding approximation, electrons move in strong periodic potentials which cannot be approximated by an average background. In this situation, we can assume that the atoms are very widely separated and atomic orbitals remain undistorted.

As an example, the ${\displaystyle H_{2}^{+}}$problem will be revisited in the second quantization language. States ${\displaystyle |1>}$ and ${\displaystyle |2>}$ denote the states of electrons locate on atom 1 and 2, respectively. The state of the two-electron system is thus given by ${\displaystyle |n_{1},n_{2}>}$, where ${\displaystyle |n_{i}>}$ is the occupation number for each atom. Define creation and annihilation operators ${\displaystyle c_{i}^{+}}$ and ${\displaystyle c_{i}}$, which obey anti-commutation relations: Failed to parse (Conversion error. Server ("https://wikimedia.org/api/rest_") reported: "Cannot get mml. TeX parse error: Double subscripts: use braces to clarify"): {\displaystyle {c_{i},c_{j}^{+}}=\delta _{i}_{,}_{j}}

Phonons: crystal vibrations

Lattice Vibration and Phonons in 1D

${\displaystyle H_{ph}^{0}=\sum _{k\lambda }\hbar \omega _{k\lambda }(a_{k\lambda }^{\dagger }+{\frac {1}{2}})}$

Acoustical and Optical Phonon in 3D

${\displaystyle H_{ph}^{0}=\sum _{\mathbf {k} \lambda }\hbar \omega _{\mathbf {k} \lambda }(a_{\mathbf {k} \lambda }^{\dagger }+{\frac {1}{2}}),:[a_{\mathbf {k} \lambda },a_{\mathbf {k} \lambda }^{\dagger }]=\delta _{\mathbf {k,k^{\prime }} }\delta _{\lambda ,\lambda ^{\prime }}}$

Derivation of Hamiltonian Electron-Phonon Coupling

The Hamiltonian for the electron-phonon interaction can be described as

${\displaystyle H=H_{el}^{0}+H_{ph}^{0}+H_{coul}+H_{int}}$

Where

${\displaystyle H_{el}^{0}=\sum _{k\sigma }E_{k}c_{k\sigma }^{\dagger }c_{k\sigma }}$

${\displaystyle H_{ph}^{0}=\sum _{k\lambda }\omega _{k\lambda }(a_{k\lambda }^{\dagger }+{\frac {1}{2}})}$

${\displaystyle H_{coul}={\frac {1}{2}}\sum _{kk^{\prime }q \atop \sigma \sigma ^{\prime }}V(q)c_{k^{\prime }+q\sigma ^{\prime }}^{\dagger }c_{k\sigma }^{\dagger }c_{k+q\sigma }c_{k^{\prime }\sigma ^{\prime }}}$

${\displaystyle H_{int}=\sum _{kk^{\prime }\sigma \lambda }g_{kk^{\prime }c_{k\sigma }^{\dagger }}c_{k^{\prime }\sigma }c_{k^{\prime }\sigma }(a_{-q\lambda }^{\dagger }+a_{q\lambda })}$

Feynman diagrams of electron-phonon coupling

Electron-phonon interaction in the lattice model

Jellium model

The Polaron problem

Linear response calculations of electron-phonon interactions

Examples