Efficient First-Principles Approach with a Pseudohybrid Density Functional for Extended Hubbard Interactions

Abstract

For fast and accurate calculations of band gaps of solids, we present an ab initio method that extends the density functional theory plus on-site Hubbard interaction (DFT+U) to include inter-site Hubbard interaction (V). This formalism is appropriate for considering various interactions such as a local Coulomb repulsion, covalent hybridizations, and their coexistence in solids. To achieve self-consistent evaluations of U and V, we adapt a recently proposed Agapito-Curtarolo-Buongiorno Nardelli pseudohybrid functional for DFT+U to implement a density functional of V and obtain band gaps of diverse bulk materials as accurate as those from GW or hybrid functionals methods with a standard DFT computational cost. Moreover, we also show that computed band gaps of few layers black phosphorous and Si(111)-(2×1) surface agree with experiments very well, thus meriting the new method for large-scale as well as high throughput calculations with higher accuracy.