Effects of self-consistency and plasmon-pole models on GW calculations for closed-shell molecules

Abstract

We present theoretical calculations of quasiparticle energies in closed-shell molecules using the GW method. We compare three different approaches: a full-frequency G0W0 (FF-G0W0) method with density functional theory (DFT-PBE) used as a starting mean field; a full-frequency GW0 (FF-GW0) method where the interacting Green's function is approximated by replacing the DFT energies with self-consistent quasiparticle energies or Hartree-Fock energies; and a G0W0 method with a Hybertsen-Louie generalized plasmon-pole model (HL GPP-G0W0). While the latter two methods lead to good agreement with experimental ionization potentials and electron affinities for methane, ozone, and beryllium oxide molecules, FF-G0W0 results can differ by more than one electron volt from experiment. We trace this failure of the FF-G0W0 method to the occurrence of incorrect self-energy poles describing shake-up processes in the vicinity of the quasiparticle energies.