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An optimally tuned range-separated hybrid starting point for <i>ab initio</i> GW plus Bethe–Salpeter equation calculations of molecules

Caroline A. McKeon, Samia M. Hamed, Fabien Bruneval, Jeffrey B. Neaton

2022The Journal of Chemical Physics46 citationsDOIOpen Access PDF

Abstract

The ab initio GW plus Bethe–Salpeter equation (GW-BSE, where G is the one particle Green's function and W is the screened Coulomb interaction) approach has emerged as a leading method for predicting excitations in both solids and molecules with a predictive power contingent upon several factors. Among these factors are the (1) generalized Kohn–Sham eigensystem used to construct the GW self-energy and to solve the BSE and (2) the efficacy and suitability of the Tamm–Dancoff approximation. Here, we present a detailed benchmark study of low-lying singlet excitations from a generalized Kohn–Sham (gKS) starting point based on an optimally tuned range-separated hybrid (OTRSH) functional. We show that the use of this gKS starting point with one-shot G0W0 and G0W0-BSE leads to the lowest mean absolute errors (MAEs) and mean signed errors (MSEs), with respect to high-accuracy reference values, demonstrated in the literature thus far for the ionization potentials of the GW100 benchmark set and for low-lying neutral excitations of Thiel’s set molecules in the gas phase, without the need for self-consistency. The MSEs and MAEs of one-shot G0W0-BSE@OTRSH excitation energies are comparable to or lower than those obtained with other functional starting points after self-consistency. Additionally, we compare these results with linear-response time-dependent density functional theory (TDDFT) calculations and find GW-BSE to be superior to TDDFT when calculations are based on the same exchange-correlation functional. This work demonstrates tuned range-separated hybrids used in combination with GW and GW-BSE can greatly suppress starting point dependence for molecules, leading to accuracy similar to that for higher-order wavefunction-based theories for molecules without the need for costlier iterations to self-consistency.

Topics & Concepts

Bethe–Salpeter equationAb initioRange (aeronautics)MoleculePhysicsPoint (geometry)Ab initio quantum chemistry methodsComputational chemistryStatistical physicsQuantum mechanicsMathematicsChemistryMaterials scienceGeometryBound stateComposite materialAdvanced Chemical Physics StudiesSpectroscopy and Quantum Chemical StudiesPerovskite Materials and Applications