Beyond quasi-particle self-consistent GW for molecules with vertex corrections

Abstract

We introduce the BSE@LBSE self-energy in the quasi-particle self-consistent GW (qsGW) framework (qsBSE@LBSE). Here, L is the two-particle response function which we calculate by solving the Bethe-Salpeter equation with the static, first-order GW kernel. The same kernel is added to directly. For a set of medium organic molecules, we show that including the vertex both in L and is crucial. This approach retains the good performance of qsGW for predicting first ionization potentials and fundamental gaps, while it greatly improves the description of electron affinities. Its good performance places qsBSE@LBSE among the best-performing electron propagator methods for charged excitations. Adding the vertex in L only, as commonly done in the solid state community, leads to devastating results for electron affinities and fundamental gaps. We also test the performance of BSE@qsGW and qsBSE@LBSE for neutral charge-transfer excitation and find both methods to perform similar. We conclude that BSE@LBSE is a promising approximation to the electronic self-energy beyond GW. We hope that future research on dynamical vertex effects, second-order vertex corrections, and full self-consistency will improve the accuracy of this method, both for charged and neutral excitation energies.

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