Role of Inorganic Cations in the Excitonic Properties of Lead Halide Perovskites

Abstract

We theoretically investigate lead iodide perovskites of general formula APbI3 for a series of metallic cations (namely Cs+, Rb+, K+, Na+ and Li+) by means of the density functional theory, GW method and Bethe-Salpeter equation including spin-orbit coupling. We demonstrate that the low-energy edges (up to 1.3 eV) of the absorption spectra are dominated by weakly bound excitons, with binding energies Eb 30-80~meV, and the corresponding intensities grow as metallic %A+ cations become lighter. The middle parts of the spectra (1.8-2.4 eV), on the other hand, contain optical dipole transitions comprising more strongly bound excitons (Eb 150-200~meV) located at PbI3. These parts of the spectra correspond to the optical-gain wavelengths which are experimentally achieved in optically-pumped perovskite lasers. Finally, the higher energy parts, from about 2.8~eV (LiPbI3) to 4.3 eV (CsPbI3), contain optical transitions with very strongly bound excitons (Eb 220-290~meV) located at the halide atoms and the empty states of the metallic cations.