Simulation of X-ray absorption spectra with orthogonality constrained density functional theory

Derricotte, Wallace D.; Evangelista, Francesco A.

doi:10.1039/c4cp05509h

Cited by 64 publications

(85 citation statements)

References 122 publications

(214 reference statements)

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“…Recently, there have been increasing interest in so-called ∆SCF methods [18][19][20][21][22][23] as an alternative to the linear-response mean-field approaches such as CI singles (CIS) and timedependent density functional theory (TDDFT) 24 . In this category, the most popular approach is based on the maximum overlap method (MOM) developed by Gilbert and Gill 22 .…”

Section: Introductionmentioning

confidence: 99%

Excited states via coupled cluster theory without equation-of-motion methods: Seeking higher roots with application to doubly excited states and double core hole states

Lee

Small

Head‐Gordon

2019

The Journal of Chemical Physics

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In this work, we revisited the idea of using the coupled-cluster ground state formalism to target excited states. Our main focus was targeting doubly excited states and double core hole states. Typical equation-of-motion (EOM) approaches for obtaining these states struggle without higher-order excitations than doubles. We showed that by using a non-aufbau determinant optimized via the maximum overlap method the CC ground state solver can target higher energy states. Furthermore, just with singles and doubles (i.e., CCSD), we demonstrated that the accuracy of ∆CCSD and ∆CCSD(T) far surpasses that of EOM-CCSD for doubly excited states. The accuracy of ∆CCSD(T) is nearly exact for doubly excited states considered in this work.For double core hole states, we used an improved ansatz for greater numerical stability by freezing core hole orbitals. The improved methods, core valence separation (CVS)-∆CCSD and CVS-∆CCSD(T), were applied to the calculation of the double ionization potential of small molecules. Even without relativistic corrections, we observed qualitatively accurate results with CVS-∆CCSD and CVS-∆CCSD(T). Remaining challenges in ∆CC include the description of open-shell singlet excited states with the single-reference CC ground state formalism as well as excited states with genuine multi-reference character. The tools and intuition developed in this work may serve as a stepping stone towards directly targeting arbitrary excited states using ground state CC methods.

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Section: Introductionmentioning

confidence: 99%

Excited states via coupled cluster theory without equation-of-motion methods: Seeking higher roots with application to doubly excited states and double core hole states

Lee

Small

Head‐Gordon

2019

The Journal of Chemical Physics

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“…They differ in the construction of occupied and virtual MOs involved in the excitation and in setting their occupation numbers, see Reference and references therein. Exemplarily, one should mention the application of a multiple hole/particle algorithm within orthogonality constrained DFT to the calculation of K ‐edge spectra . Moreover, state‐following algorithms can be applied to avoid the variational collapse without explicit setting the orthogonality constraint.…”

Section: Theoretical Methodsmentioning

confidence: 99%

Theoretical X‐ray spectroscopy of transition metal compounds

Bokarev

Kühn

2019

WIREs Comput Mol Sci

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X-ray spectroscopy is one of the most powerful tools to access structure and properties of matter in different states of aggregation as it allows to trace atomic and molecular energy levels in course of various physical and chemical processes. Xray spectroscopic techniques probe the local electronic structure of a particular atom in its environment, in contrast to ultraviolet/visible (UV/Vis) spectroscopy, where transitions generally occur between delocalized molecular orbitals. Complementary information is provided by using a combination of different absorption, emission, scattering as well as photo-and autoionization X-ray methods. However, interpretation of the complex experimental spectra and verification of experimental hypotheses is a nontrivial task and powerful first principles theoretical approaches that allow for a systematic investigation of a broad class of systems are needed. Focusing on transition metal compounds, L-edge spectra are of particular relevance as they probe the frontier d-orbitals involved in metal-ligand bonding. Here, neardegeneracy effects in combination with spin-orbit coupling lead to a complicated multiplet energy level structure, which poses a serious challenge to quantum chemical methods. Multiconfigurational self-consistent field (MCSCF) theory has been shown to be capable of providing a rather detailed understanding of experimental X-ray spectroscopy. However, it cannot be considered as a "blackbox" tool and its application requires not only a command of formal theoretical aspects, but also a broad knowledge of already existing applications. Both aspects are covered in this overview.

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“…This is generally referred to as the Δ method. [ 1–10 ] In practice, however, it is often difficult, if not impossible, to converge to the desired ionized state. Furthermore, because the magnitude of IPs is typically much smaller than the total energies per se, it is well‐known that the Δ method suffers from the imbalanced treatments of the initial and the final states.…”

Section: Introductionmentioning

confidence: 99%

“…In principle, IPs can be straightforwardly obtained at any level of theory via calculations of the ground-and excited-state energies of the (N−1)-electron system with respect to the ground-state energy of the N-electron system.This is generally referred to as the Δ method. [1][2][3][4][5][6][7][8][9][10] In practice, however, it is often difficult, if not impossible, to converge to the desired ionized state. Furthermore, because the magnitude of IPs is typically much smaller than the total energies per se, it is well-known that the Δ method suffers from the imbalanced treatments of the initial and the final states.These problems can be effectively circumvented in the direct methods, where IPs are computed without relying on explicit total energy evaluations of the initial and the final states for their differences.…”

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confidence: 99%

Extended Koopmans' theorem at the second‐order perturbation theory

2020

J Comput Chem

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The extended Koopmans' theorem (EKT), when combined with the second‐order Møller−Plesset (MP2) perturbation theory through the relaxed density matrix approach [J. Cioslowski, P. Piskorz, and G. Liu, J. Chem. Phys. 1997, 107, 6,804], provides a straightforward way to calculate the ionization potentials (IPs) as an one electron quantity. However, such an EKT‐MP2 method often suffers from the negative occupation problem, failing to provide the complete IP spectra for a system of interest. Here a small positive number scheme is proposed to cure this problem so as to remove the associated unphysical results. In order to obtain an in‐depth physical interpretation of the EKT‐MP2 method, we introduce a Koopmans‐type quantity, named KT‐MP2, based on which the respective contribution from the relaxation and the correlation parts in the EKT‐MP2 results are recognized. Furthermore, the close relationship between the EKT‐MP2 method and the derivative approach of the MP2 energy with respect to the orbital occupation numbers [N. Q. Su and X. Xu, J. Chem. Theory Comput. 2015, 11, 4,677] is revealed. When these MP2‐based methods are applied to a set of atoms and molecules, new insights are gained on the role played by the relaxation and the correlation effects in the electron ionization processes.

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Simulation of X-ray absorption spectra with orthogonality constrained density functional theory

Cited by 64 publications

References 122 publications

Excited states via coupled cluster theory without equation-of-motion methods: Seeking higher roots with application to doubly excited states and double core hole states

Excited states via coupled cluster theory without equation-of-motion methods: Seeking higher roots with application to doubly excited states and double core hole states

Theoretical X‐ray spectroscopy of transition metal compounds

Extended Koopmans' theorem at the second‐order perturbation theory

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