Excited States, Symmetry Breaking, and Unphysical Solutions in State-Specific CASSCF Theory

Marie, Antoine; Burton, Hugh G. A.

doi:10.1021/acs.jpca.3c00603

Cited by 11 publications

(24 citation statements)

References 146 publications

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“…In state-specific electronic structure methods, ground and excited states can be found as stationary points on the electronic energy landscape, the surface described by the variation of the energy as a function of the electronic degrees of freedom . The ground state corresponds to a global minimum, while the excited states are typically saddle points. ,,,, Within the KS method, the excited stationary states correspond to higher-energy solutions of the KS equations and have nonaufbau orbital occupations. Therefore, they can be found by solving the KS equations through SCF algorithms based on sequential eigendecomposition of the KS Hamiltonian matrix if a given nonaufbau occupation of the orbitals can be preserved during the iterations.…”

Section: Methodsmentioning

confidence: 99%

“…Due to the nonlinearity of the orbital optimization, orbital-optimized calculations can be affected by the presence of stationary points on the electronic energy surface without a clear association with a particular electronic state. ,, In the context of intramolecular charge transfer excitations, it has been shown that orbital-optimized calculations can converge on solutions with significantly different degrees of charge transfer depending on the method used. This is exemplified by the A 1 LUMO + 1 ← HOMO charge transfer excitation in the twisted PP molecule .…”

Section: Methodsmentioning

confidence: 99%

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Orbital-Optimized Versus Time-Dependent Density Functional Calculations of Intramolecular Charge Transfer Excited States

Selenius,

Sigurdarson,

Schmerwitz

et al. 2024

J. Chem. Theory Comput.

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The performance of time-independent, orbital-optimized calculations of excited states is assessed with respect to charge transfer excitations in organic molecules in comparison to the linear-response time-dependent density functional theory (TD-DFT) approach. A direct optimization method to converge on saddle points of the electronic energy surface is used to carry out calculations with the local density approximation (LDA) and the generalized gradient approximation (GGA) functionals PBE and BLYP for a set of 27 excitations in 15 molecules. The time-independent approach is fully variational and provides a relaxed excited state electron density from which the extent of charge transfer is quantified. The TD-DFT calculations are generally found to provide larger charge transfer distances compared to the orbital-optimized calculations, even when including orbital relaxation effects with the Z-vector method. While the error on the excitation energy relative to theoretical best estimates is found to increase with the extent of charge transfer up to ca. −2 eV for TD-DFT, no correlation is observed for the orbital-optimized approach. The orbital-optimized calculations with the LDA and the GGA functionals provide a mean absolute error of ∼0.7 eV, outperforming TD-DFT with both local and global hybrid functionals for excitations with a long-range charge transfer character. Orbital-optimized calculations with the global hybrid functional B3LYP and the range-separated hybrid functional CAM-B3LYP on a selection of states with short-and long-range charge transfer indicate that inclusion of exact exchange has a small effect on the charge transfer distance, while it significantly improves the excitation energy, with the best-performing functional CAM-B3LYP providing an absolute error typically around 0.15 eV.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Orbital-Optimized Versus Time-Dependent Density Functional Calculations of Intramolecular Charge Transfer Excited States

Selenius,

Sigurdarson,

Schmerwitz

et al. 2024

J. Chem. Theory Comput.

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“…The occurrence of discontinuities can be due to an unsuitable choice of the active space such that the global minimum of the CASSCF energy is obtained by a switch between active and doubly occupied or virtual orbitals. However, even when the active space is blameless, trapping in secondary minima may occur, depending on the convergence algorithm and on the choice of the initial guess orbitals. − As a result of such failures of computational methods, the predictions of the theory discussed in the previous sections may be occasionally contradicted by actual calculations.…”

Section: Application In the Study Of Crossing Seams In H2cl+mentioning

confidence: 99%

Topology of Conical Intersection Seams and the Geometric Phase

Morreale,

Persico

2024

J. Phys. Chem. A

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In this paper, we demonstrate two topological properties of crossing seams, that is, the sets of points in the Ndimensional space of nuclear coordinates where two electronic eigenstates are degenerate. We shall examine the typical case of states of the same spin with accidental degeneracies, whereby the crossing seam is of dimension N − 2. The first property we demonstrate is that a crossing seam has no boundary, therefore, it must either extend asymptotically to infinite values of one or more coordinates or wrap on itself. The second property is that two (or more) crossing seams can intersect each other but in such a way that neither of them ends at the intersection. When N = 3, the crossing seam is a line in a 3D space; this is so in triatomic molecules but also in reduced dimensionality treatments of larger polyatomics. The above-mentioned rules then mean that the crossing seam is a line of infinite length or a closed loop and can split into three branches but not in two. The example of the first two excited 1 A′ states of H 2 Cl + illustrates these rules and shows their usefulness for computational search and characterization of crossing seams.

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“…Instead, one may optimize the orbitals for the excited state of interest (described with an appropriate reference), followed by a separate CI calculation, in a so-called state-specific approach (ΔCI). There has been a recent surge in the development of state-specific methods, covering single-reference and multiconfigurational self-consistent field, − density functional theory, − perturbation theory, − quantum Monte Carlo, − and coupled-cluster (CC) − methods. In particular, by employing a minimal configuration state function (CSF) reference, we have recently shown that excitation-based ΔCI models deliver far more accurate excitation energies than their ground-state-based analogs …”

Section: Introductionmentioning

confidence: 99%

Seniority and Hierarchy Configuration Interaction for Radicals and Excited States

Kossoski,

Loos

2023

J. Chem. Theory Comput.

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Hierarchy configuration interaction (hCI) has recently been introduced as an alternative configuration interaction (CI) route combining excitation degree and seniority number and has been shown to efficiently recover both dynamic and static correlations for closedshell molecular systems [J. Phys. Chem. Lett. 2022, 13, 4342]. Here we generalize hCI for an arbitrary reference determinant, allowing calculations for radicals and excited states in a state-specific way. We gauge this route against excitation-based CI (eCI) and seniority-based CI (sCI) by evaluating how different ground-state properties of radicals converge to the full CI limit. We find that hCI outperforms or matches eCI, whereas sCI is far less accurate, in line with previous observations for closed-shell molecules. Employing second-order Epstein−Nesbet (EN2) perturbation theory as a correction significantly accelerates the convergence of hCI and eCI. We further explore various hCI and sCI models to calculate the excitation energies of closed-and open-shell systems. Our results underline that the choice of both the reference determinant and the set of orbitals drives the fine balance between correlation of ground and excited states. Statespecific hCI2 and higher-order models perform similarly to their eCI counterparts, whereas lower orders of hCI deliver poor results unless supplemented by the EN2 correction, which substantially improves their accuracy. In turn, sCI1 produces decent excitation energies for radicals, encouraging the development of related seniority-based coupled-cluster methods.

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Excited States, Symmetry Breaking, and Unphysical Solutions in State-Specific CASSCF Theory

Cited by 11 publications

References 146 publications

Orbital-Optimized Versus Time-Dependent Density Functional Calculations of Intramolecular Charge Transfer Excited States

Orbital-Optimized Versus Time-Dependent Density Functional Calculations of Intramolecular Charge Transfer Excited States

Topology of Conical Intersection Seams and the Geometric Phase

Seniority and Hierarchy Configuration Interaction for Radicals and Excited States

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