[Jae-Mo Lihm and Prof. Cheol-Hwan Park] Development of Wannier Function Perturbation Theory
Abstract: Thanks to the nearsightedness principle, the low-energy electronic structure of solids can be represented by localized states such as the Wannier functions. Wannier functions are actively being applied to a wide range of phenomena in condensed matter systems. However, the Wannier-function-based representation is limited to a small number of bands and thus cannot describe the change of wave functions due to various kinds of perturbations, which require sums over an infinite number of bands. Here, we introduce the concept of the Wannier function perturbation, which provides a localized representation of wave function perturbations. Wannier function perturbation theory allows efficient calculation of numerous quantities involving wave function perturbation, among which we provide three applications. First, we calculate the temperature-dependent indirect optical absorption spectra of silicon near the absorption edge nonadiabatically, i.e., differentiating phonon-absorption and phonon-emission processes, and without arbitrary temperature-dependent shifts in energy. Second, we establish a theory to calculate the shift spin conductivity without any band-truncation error. Unlike the shift charge conductivity, an exact calculation of the shift spin conductivity is not possible within the conventional Wannier function methods because it cannot be obtained from geometric quantities for low-energy bands. We apply the theory to monolayer WTe2. Third, we calculate the spin Hall conductivity of the same material again without any band-truncation error. Wannier function perturbation theory is a versatile method that can be readily applied to calculate a wide range of quantities related to various kinds of perturbations.
Jae-Mo Lihm and Cheol-Hwan Park, “Wannier Function Perturbation Theory: Localized Representation and Interpolation of Wave Function Perturbation,” Phys. Rev. X 11, 041053 (2021).
Link: https://journals.aps.org/prx/abstract/10.1103/PhysRevX.11.041053