Hierarchy Configuration Interaction: Combining Seniority Number and Excitation Degree

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We introduce and benchmark a systematically improvable route for excited-state calculations, labeled state-specific configuration interaction (ΔCI), which is a particular realization of multiconfigurational self-consistent field and multireference configuration interaction. Starting with a reference built from optimized configuration state functions, separate CI calculations are performed for each targeted state (hence, state-specific orbitals and determinants). Accounting for single and double excitations produces the ΔCISD model, which can be improved with second-order Epstein−Nesbet perturbation theory (ΔCISD+EN2) or a posteriori Davidson corrections (ΔCISD+Q). These models were gauged against a vast and diverse set of 294 reference excitation energies. We have found that ΔCI is significantly more accurate than standard ground-statebased CI, whereas close performances were found between ΔCISD and EOM-CC2 and between ΔCISD+EN2 and EOM-CCSD. For larger systems, ΔCISD+Q delivers more accurate results than EOM-CC2 and EOM-CCSD. The ΔCI route can handle challenging multireference problems, singly and doubly excited states, from closed-and open-shell species, with overall comparable accuracy and thus represents a promising alternative to more established methodologies. In its current form, however, it is reliable only for relatively low-lying excited states.

Section: Types Of Excitationsmentioning

confidence: 99%

State-Specific Configuration Interaction for Excited States

Kossoski

Loos

2023

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“…Obviously, to fully exploit the potential of first-principle simulations, it is mandatory to select a reliable and robust protocol, ideally not requiring extensive computational resources. There is a vast computational spectroscopy literature covering a wide palette of aspects, including (i) – (iii) and suggesting strategies to select the most appropriate models for treating different types of states and compounds. − However, by and large, published works either treat these aspects separately or provide a detailed analysis for a selected dye or a small set of closely related compounds. The aim of the present contribution is to propose an efficient protocol to overcome some of these limitations and discuss the accuracy and reliability of electronic and vibrational structure methods for simulating vibrationally-resolved electronic absorption spectra, including nonempirical estimations of the inhomogeneous broadening.…”

Section: Introductionmentioning

confidence: 99%

Cost-Effective Simulations of Vibrationally-Resolved Absorption Spectra of Fluorophores with Machine-Learning-Based Inhomogeneous Broadening

Petrusevich

Bousquet

Ośmiałowski

et al. 2023

The results of electronic and vibrational structure simulations are an invaluable support for interpreting experimental absorption/emission spectra, which stimulates the development of reliable and cost-effective computational protocols. In this work, we contribute to these efforts and propose an efficient first-principle protocol for simulating vibrationally-resolved absorption spectra, including nonempirical estimations of the inhomogeneous broadening. To this end, we analyze three key aspects: (i) a metric-based selection of density functional approximation (DFA) so to benefit from the computational efficiency of time-dependent density function theory (TD-DFT) while safeguarding the accuracy of the vibrationally-resolved spectra, (ii) an assessment of two vibrational structure schemes (vertical gradient and adiabatic Hessian) to compute the Franck–Condon factors, and (iii) the use of machine learning to speed up nonempirical estimations of the inhomogeneous broadening. In more detail, we predict the absorption band shapes for a set of 20 medium-sized fluorescent dyes, focusing on the bright ππ ★ S0 → S1 transition and using experimental results as references. We demonstrate that, for the studied 20-dye set which includes structures with large structural variability, the preselection of DFAs based on an easily accessible metric ensures accurate band shapes with respect to the reference approach and that range-separated functionals show the best performance when combined with the vertical gradient model. As far as band widths are concerned, we propose a new machine-learning-based approach for determining the inhomogeneous broadening induced by the solvent microenvironment. This approach is shown to be very robust offering inhomogeneous broadenings with errors as small as 2 cm–1 with respect to genuine electronic-structure calculations, with a total CPU time reduced by 98%.

“…By taking into account all single and double excitations, one gets CI with singles and doubles (CISD) with a computational cost scaling as scriptO false( N 6 false) (where N is the number of one-electron basis functions), while adding the triples yields CI with singles, doubles, and triples (CISDT) scaling as scriptO false( N 8 false) , and so on. Alternatively, one can systematically increase the seniority number (i.e., the number of unpaired electrons) or the hierarchy parameter (average of the excitation degree and half the seniority number). − Unfortunately, all these methods require considering a huge number of electronic configurations, most of them contributing very little to the energies and/or properties of interest.…”

Section: Introductionmentioning

confidence: 99%

Ground- and Excited-State Dipole Moments and Oscillator Strengths of Full Configuration Interaction Quality

Damour

Quintero-Monsebaiz

Caffarel

et al. 2022

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We report ground-and excited-state dipole moments and oscillator strengths (computed in different "gauges" or representations) of full configuration interaction (FCI) quality using the selected configuration interaction method known as Configuration Interaction using a Perturbative Selection made Iteratively (CIPSI). Thanks to a set encompassing 35 ground-and excited-state properties computed in 11 small molecules, the present near-FCI estimates allow us to assess the accuracy of high-order coupled-cluster (CC) calculations including up to quadruple excitations. In particular, we show that incrementing the excitation degree of the CC expansion (from CC with singles and doubles (CCSD) to CC with singles, doubles, and triples (CCSDT) or from CCSDT to CC with singles, doubles, triples, and quadruples (CCSDTQ)) reduces the average error with respect to the near-FCI reference values by approximately 1 order of magnitude.