cgk said:The bands only exist in k-space, since the effective mean field one-particle Hamiltonian (Fock operator/Kohn-Sham operator), of which the e(k) are the eigenvalues, is diagonal in k-space, but not in real space.
If you transform the eigenstates of this operator (the crystal orbitals) into real space, you get the Wannier orbitals, which look closely like normal atomic orbitals (in particular, they are identical in each unit cell). But these Wannier orbitals do not diagonalize the effective one-particle Hamiltonian anymore, so there is no e(r) relation in this sense.
The energy band in K space refers to the distribution of energy states in momentum space, while the energy band in real space refers to the distribution of energy states in physical space. In other words, K space represents the momentum of electrons, while real space represents their position.
The energy band in K space and in real space are related by the Fourier transform. This mathematical operation allows for the conversion between momentum and position coordinates, and shows the relationship between the two energy band representations.
The energy band in K space provides information about the electronic structure, such as the band gap and the density of states. The energy band in real space provides information about the spatial distribution of electrons, such as their localization and movement.
The energy band in K space and in real space both play important roles in determining the electronic and optical properties of materials. The energy band in K space affects the conductivity and mobility of electrons, while the energy band in real space affects the optical absorption and emission spectra.
Yes, the energy band in K space and in real space can be manipulated through various techniques such as doping, applying an electric field, or creating defects in the material. These manipulations can alter the energy band structure and subsequently change the properties of the material.