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Weight dependence of local exchange–correlation functionals in ensemble density-functional theory: double excitations in two-electron systems

Clotilde Marut, Bruno Senjean, Emmanuel Fromager, Pierre-François Loos

2020Faraday Discussions31 citationsDOIOpen Access PDF

Abstract

Gross-Oliveira-Kohn (GOK) ensemble density-functional theory (GOK-DFT) is a time-independent extension of density-functional theory (DFT) which allows the computation of excited-state energies via the derivatives of the ensemble energy with respect to the ensemble weights. Contrary to the time-dependent version of DFT (TD-DFT), double excitations can be easily computed within GOK-DFT. However, to take full advantage of this formalism, one must have access to a weight-dependent exchange-correlation functional in order to model the infamous ensemble derivative contribution to the excitation energies. In the present article, we discuss the construction of first-rung (i.e., local) weight-dependent exchange-correlation density-functional approximations for two-electron atomic and molecular systems (He and H2) specifically designed for the computation of double excitations within GOK-DFT. In the spirit of optimally-tuned range-separated hybrid functionals, a two-step system-dependent procedure is proposed to obtain accurate energies associated with double excitations.

Topics & Concepts

ComputationExcitationExtension (predicate logic)Statistical physicsPhysicsStatistical ensembleEnergy (signal processing)Derivative (finance)Order (exchange)Microcanonical ensembleCanonical ensembleApproximations of πQuantum mechanicsDensity functional theoryFirst orderMathematicsTotal energyRange (aeronautics)Quantum, superfluid, helium dynamicsAdvanced Chemical Physics StudiesInorganic Fluorides and Related Compounds
Weight dependence of local exchange–correlation functionals in ensemble density-functional theory: double excitations in two-electron systems | Litcius