Phonons: Theory: Difference between revisions

To understand them we start by looking at the Taylor expansion of the total energy (${\displaystyle E}$) around the set of equilibrium positions of the nuclei (${\displaystyle \{\mathbf{R}^0\}}$)

${\displaystyle E(\{\mathbf{R}\})= E(\{\mathbf{R}^0\})+ \sum_{I\alpha} \frac{\partial E(\{\mathbf{R^0}\})}{\partial R_{I\alpha}} (R_{I\alpha}-R^0_{I\alpha})+ \sum_{I\alpha J\beta} \frac{\partial E(\{\mathbf{R}^0\})}{\partial R_{I\alpha} \partial R_{J\beta}} (R_{I\alpha}-R^0_{I\alpha}) (R_{J\beta}-R^0_{J\beta})+ \mathcal{O}(\mathbf{R}^3), }$

where ${\displaystyle \{\mathbf{R}\}}$ the positions of the nuclei. The first term in the expansion corresponds to the forces

${\displaystyle F_{I\alpha} (\{\mathbf{R}^0\}) = - \left. \frac{\partial E(\{\mathbf{R}\})}{\partial R_{I\alpha}} \right|_{\mathbf{R} =\mathbf{R^0}} }$,

and the second to the second-order force-constants

${\displaystyle C_{I\alpha J\beta} (\{\mathbf{R}^0\}) = \left. \frac{\partial E(\{\mathbf{R}\})}{\partial R_{I\alpha} \partial R_{J\beta}} \right|_{\mathbf{R} =\mathbf{R^0}} = - \left. \frac{\partial F_{I\alpha}(\{\mathbf{R}\})}{\partial R_{J\beta}} \right|_{\mathbf{R} =\mathbf{R^0}}. }$

We can define a variable that corresponds to the displacement of the atoms with respect to the equilibrium position ${\displaystyle R_{I\alpha} = R^0_{I\alpha}+u_{I\alpha} }$ which leads to

${\displaystyle E(\{\mathbf{R}\})= E(\{\mathbf{R}^0\})+ \sum_{I\alpha} -F_{I\alpha} (\{\mathbf{R}^0\}) u_{I\alpha}+ \sum_{I\alpha J\beta} C_{I\alpha J\beta} (\{\mathbf{R}^0\}) u_{I\alpha} u_{J\beta} + \mathcal{O}(\mathbf{R}^3) }$

If we take the system to be in equilibrium, the forces on the atoms are zero and then the Hamiltonian of the system is

${\displaystyle H = \frac{1}{2} \sum_{I\alpha} M_I \ddot{u}^2_{I\alpha} + \frac{1}{2} \sum_{I\alpha J\beta} C_{I\alpha J\beta} u_{I\alpha} u_{J\beta}, }$

and the equation of motion

${\displaystyle M_I \ddot{u}^2_{I\alpha} = - C_{I\alpha J\beta} u_{J\beta} }$

Using the following ansatz

${\displaystyle \mathbf{u}^\mu_{I\alpha}(\mathbf{q},t) = \frac{1}{2} \frac{1}{\sqrt{M_I}} \left\{ A^\mu(\mathbf{q}) \xi^{\mu }_{I\alpha}(\mathbf{q}) e^{ i [\mathbf{q} \cdot \mathbf{\mathbf{R}}_I -\omega_\mu(\mathbf{q})t]}+ A^{\mu*}(\mathbf{q}) \xi^{\mu*}_{I\alpha}(\mathbf{q}) e^{-i [\mathbf{q} \cdot \mathbf{\mathbf{R}}_I -\omega_\mu(\mathbf{q})t]} \right\} }$

where ${\displaystyle \xi^{\mu }_{I\alpha}(\mathbf{q})}$ are the phonon mode eigenvectors. Replacing we obtain the following eigenvalue problem

${\displaystyle \sum_{J\beta} D_{I\alpha J\beta} (\mathbf{q}) \xi^{\mu }_{J\beta}(\mathbf{q}) = \omega^\mu(\mathbf{q})^2 \xi^{\mu }_{I\alpha}(\mathbf{q}) }$

with

${\displaystyle D_{I\alpha J\beta} (\mathbf{q}) = \frac{1}{\sqrt{M_I M_J}} C_{I\alpha J\beta} e^{i\mathbf{q} \cdot (\mathbf{R}_J-\mathbf{R}_I)} }$

the dynamical matrix in the harmonic approximation. Now by solving the eigenvalue problem above we can obtain the phonon modes ${\displaystyle \xi^{\mu }_{I\alpha}(\mathbf{q})}$ and frequencies ${\displaystyle \omega^\mu(\mathbf{q})^2}$ at any arbitrary q point.