Assessing the G0W0(1)0 approach: Beyond G0W0 with Hedin's full second-order self-energy contribution

Abstract

We present and benchmark a self-energy approach for quasiparticle energy calculations that goes beyond Hedin's GW approximation by adding the full second-order self-energy (FSOS-W) contribution. The FSOS-W diagram involves two screened Coulomb interaction (W) lines and adding the FSOS-W to the GW self-energy can be interpreted as first-order vertex correction to GW (GW(1)). Our FSOS-W implementation is based on the resolution-of-identity technique and exhibits better than O(N5) scaling with system size for small to medium-sized molecules. We then present one-shot GW(1) (G0W0(1)0) benchmarks for the GW100 test set and a set of 24 acceptor molecules. For semilocal or hybrid density functional theory starting points, G0W0(1)0 systematically outperforms G0W0 for the first vertical ionization potentials (vIPs) and electron affinities (vEAs) of both test sets. Finally, we demonstrate that a static FSOS-W self-energy significantly underestimates the quasiparticle energies.