Direct Extraction of Excitation Energies from Ensemble Density-Functional Theory

Yang, Zeng-hui; Pribram‐Jones, Aurora; Burke, Kieron; Ullrich, Carsten A.

doi:10.1103/physrevlett.119.033003

Cited by 63 publications

(79 citation statements)

References 50 publications

(94 reference statements)

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“…Note also that LIM applies to any approximate ensemble energies (WIDFA or GIC, with or without range separation 44 ). Let us finally mention that other approaches can be used for extracting excitation energies from an ensemble, in particular by making another choice for the ensemble weights and by using derivatives of the ensemble energy for a direct extraction 30 . In the latter case, weight dependence of the xc functional must be introduced, which is not trivial.…”

Section: Extraction Of Excitation Energies By Linear Interpolationmentioning

confidence: 99%

“…The exchange-correlation ensemble-density-functional energy depends in principle on these weights. It still remains a challenge to model this weight-dependence which actually plays a crucial role in the calculation of excitation energies 13,30,32,33,38,39 . The recent resurgence of eDFT in the literature is partly arXiv:1708.03478v2 [physics.chem-ph] 16 Oct 2017 due to the fact that, when combined with wavefunction theory by means of range separation for example 31,32 , it leads to a rigorous state-averaged multiconfigurational DFT.…”

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confidence: 99%

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Combining extrapolation with ghost interaction correction in range-separated ensemble density functional theory for excited states

Alam

Deur

Knecht

et al. 2017

The Journal of Chemical Physics

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The extrapolation technique of Savin [J. Chem. Phys. 140, 18A509 (2014)], which was initially applied to range-separated ground-state-density-functional Hamiltonians, is adapted in this work to ghost-interactioncorrected (GIC) range-separated ensemble density-functional theory (eDFT) for excited states. While standard extrapolations rely on energies that decay as µ −2 in the large range-separation-parameter µ limit, we show analytically that (approximate) range-separated GIC ensemble energies converge more rapidly (as µ −3 ) towards their pure wavefunction theory values (µ → +∞ limit), thus requiring a different extrapolation correction. The purpose of such a correction is to further improve on the convergence and, consequently, to obtain more accurate excitation energies for a finite (and, in practice, relatively small) µ value. As a proof of concept, we apply the extrapolation method to He and small molecular systems (viz. H 2 , HeH + and LiH), thus considering different types of excitations like Rydberg, charge transfer and double excitations. Potential energy profiles of the first three and four singlet Σ + excitation energies in HeH + and H 2 , respectively, are studied with a particular focus on avoided crossings for the latter. Finally, the extraction of individual state energies from the ensemble energy is discussed in the context of range-separated eDFT, as a perspective.

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Section: Extraction Of Excitation Energies By Linear Interpolationmentioning

confidence: 99%

mentioning

confidence: 99%

Combining extrapolation with ghost interaction correction in range-separated ensemble density functional theory for excited states

Alam

Deur

Knecht

et al. 2017

The Journal of Chemical Physics

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“…Conical intersections, charge transfer states and Rydberg states are among those cases where practical implementations of TDDFT struggle to provide a physical model. More recently, multiconfigurational DFT methods, such as ensemble DFT [1][2][3][4][5], constrained DFT [6][7][8], block-localized DFT [9,10], DFT/MRCI [11], and even flavors of ground state DFT [12] have been proposed as innovative protocols for extracting excitation energies in a computationally efficient way while still making use of density functionals in their formulation.…”

Section: Introductionmentioning

confidence: 99%

Capturing multireference excited states by constrained-density-functional theory

2020

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The computation of excited electronic states with commonly employed (approximate) methods is challenging, typically yielding states of lower quality than the corresponding ground state for a higher computational cost. In this work, we present a mean field method that extends the previously proposed eXcited Constrained DFT (XCDFT) from single Slater determinants to ensemble 1-RDMs for computing low-lying excited states. The method still retains an associated computational complexity comparable to a semilocal DFT calculation while at the same time is capable of approaching states with multireference character. We benchmark the quality of this method on well-established test sets, finding good descriptions of the electronic structure of multireference states and maintaining an overall accuracy for the predicted excitation energies comparable to semilocal TDDFT.

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“…EEXX calculations can yield good results in small atoms, [38][39][40] even for excitations that are very difficult for approximations to time-dependent Kohn-Sham theory. EEXX can be calculated in two ways: it can be obtained as a functional of the exact density, using the exact orbitals, which is the course we pursue in this work to avoid densitydriven errors 64 .…”

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confidence: 99%

“…EDFT can yield energy differences directly, as discussed in detail below. Indeed, excited state EDFT has seen increasing interest of late [33][34][35][36][37][38][39][40] as a potential alternative to TDDFT for excitation energies. This recent resurgence of GOK EDFT mirrors a growing interest in more general forms of EDFT, which can deal, e.g., with degenerate ground states 30,[41][42][43][44] and "open" systems with a noninteger number of electrons.…”

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confidence: 99%

Charge transfer excitations from exact and approximate ensemble Kohn-Sham theory

Gould¹,

Pittalis²,

Kronik³

2018

Preprint

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By studying the lowest excitations of an exactly solvable one-dimensional molecular model, we show that components of Kohn-Sham ensembles can be used to describe charge transfers. Furthermore, we compute the approximate excitation energies obtained by using thee exact ensemble densities in the recently formulated ensemble Hartree-exchange theory [Gould and Pittalis, Phys. Rev. Lett. 119, 243001 (2017)]. Remarkably, our results show that triplet excitations are accurately reproduced across a dissociation curve in all cases tested, even in systems where ground state energies are poor due to strong static correlations. Singlet excitations exhibit larger deviations from exact results but are still reproduced semi-quantitatively.

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Direct Extraction of Excitation Energies from Ensemble Density-Functional Theory

Cited by 63 publications

References 50 publications

Combining extrapolation with ghost interaction correction in range-separated ensemble density functional theory for excited states

Combining extrapolation with ghost interaction correction in range-separated ensemble density functional theory for excited states

Capturing multireference excited states by constrained-density-functional theory

Charge transfer excitations from exact and approximate ensemble Kohn-Sham theory

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