Abstract
We propose a novel approach for characterising the electron spectrum of disordered crystals constructed from a Hamiltonian of electrons as well as phonons and a diagram approach for Green’s function. The system’s electronic states were modelled by means of the multi-band, tight-binding approach. The system’s Hamiltonian is described based on the electron wave functions at the field of the atom nucleus. Our novel approach incorporates the long-range Coulomb interplay of electrons located in different lattice positions. Explicit interpretations of Green’s functions are derived using a diagram method. Equations are obtained for the vertex components for the mass operators of the electron–electron as well aselectron–phonon interplays. A system of equations for the spectrum of elementary excitations in the crystal is obtained, in which the vertex components for the mass operators of electron–electron as well as electron–phonon interplays are renormalised. Thismakes it possible to perform numerical computationsfor the system’s energy spectrum with a predetermined accuracy. In contrast to other approaches in which electron correlations are only taken into account in the limiting cases of an infinitely large and infinitesimal electron density, in this method, electron correlations are described in the general case of an arbitrary density. We obtained the cluster expansion of the density of states (DOS) of the disordered systems. We demonstrate that the addition of the electron-scattering mechanismsto the clusters is decreasing. This happens due to a growing number of positions in the cluster, which hang ontothe small parameter. The computing exactness is fixed by a small parameter for cluster expansion of Green’s functions of electrons as well as phonons.
Highlights
Breakthroughs in characterising the disordered systems are firmly connected with the evolution of the pseudopotential method [1]
A fundamental breakthrough was accomplished duringthe research of the electronic structure, as well as properties of the system due to the application of the ultrasoft pseudopotentials developed by Vanderbilt [2,3] as well as the projector augmented waves theory developed by Blochl [4,5]
Our contribution reveals an original method of characterisingthe electronic spectrum for thedisarrangedcrystals based on the Hamiltonian of electrons as well as phonons, and a diagram approach for the Green’s function finding
Summary
Breakthroughs in characterising the disordered systems are firmly connected with the evolution of the pseudopotential method [1]. From the previously mentioned equation, we can obtain the electron energetic spectrum wave functions as well as the value of the complete energy functional. Effects related tothe electronic localised states, as well as lattice vibrations, happen at disordered crystals. These effects cannot be characterised using the model for a perfect crystal. Crucial accomplishments in illustration of the effects of the disordered systems are connected with the implementation of the tight-binding model for multi-electron scattering, which includes an estimation of the coherent potential. Beginning out of Slater’s and Koster’s contributions [20,21], the tight-binding model was widely used in electronic structure computations and in the explanation of the ideal crystal characteristics. Energetic spectrumcomputation accuracy is based upon re-normalisation of the vertex parts of the electron–electron as well as electron–phonon mass operators
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