Electron-phonon interactions theory: Difference between revisions

Electron-phonon interactions from statistical sampling

The probability distribution of finding an atom within the coordinates ${\displaystyle \kappa +d\kappa }$ (where ${\displaystyle \kappa }$ denotes the Cartesian coordinates as well as the atom number) at temperature ${\displaystyle T}$ in the harmonic approximation is given by the following expression^[1][2]

${\displaystyle dW_{\nu }(\kappa ,T)={\frac {1}{2\pi \langle u_{\nu \kappa }^{2}\rangle }}e^{-\kappa ^{2}/(2\langle u_{\nu \kappa }^{2}\rangle )}d\kappa ,}$

where the mean-square displacement of the harmonic oscillator is given as

${\displaystyle \langle u_{\nu \kappa }^{2}\rangle ={\frac {\hbar }{2M_{\kappa }\omega _{\nu }}}\coth {\frac {\hbar \omega _{\nu }}{2k_{B}T}}.}$

Here ${\displaystyle M_{\kappa }}$, ${\displaystyle \nu }$ and ${\displaystyle \omega _{\nu }}$ denote the mass, phonon eigenmode and phonon eigenfrequency, respectively. The equation for ${\displaystyle dW}$ is valid at any temperature and the high (Maxwell--Boltzmann distribution) and low temperature limits are easily regained. In order to obtain an observable ${\displaystyle O(T)}$ at a given temperature ${\displaystyle T</math,theaverageoftheobservablesampledatdifferentcoordinatesets<math>x_{T}^{{\textrm {MC}},i}}$ with sample size ${\displaystyle n}$ is taken

${\displaystyle \langle O(T)\rangle ={\frac {1}{n}}\sum \limits _{i=1}^{n}O(x_{T}^{\textrm {MC,i}}).}$

Each set ${\displaystyle i}$ is obtained from the equilibrium atomic positions ${\displaystyle x_{\textrm {eq}}}$ as

${\displaystyle x_{T}^{\textrm {MC,i}}=x_{\textrm {eq}}+\Delta \tau ^{\textrm {MC,i}}}$

with the displacement

${\displaystyle \Delta \tau ^{\textrm {MC,i}}={\sqrt {\frac {1}{M_{\kappa }}}}\sum \limits _{\nu }^{3(N-1)}\varepsilon _{\kappa ,\nu }{\mathcal {N}}.}$

Here ${\displaystyle \varepsilon _{\kappa ,\nu }}$ denotes the unit vector of eigenmode ${\displaystyle \nu }$ on atom ${\displaystyle \kappa }$. The magnitude of the displacement in each Cartesian direction is obtained from the normal-distributed random variable ${\displaystyle {\mathcal {N}}}$ with a probability distribution according to ${\displaystyle dW}$.