Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian

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Standard

Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian. / Høyer, Nicolai Machholdt; Kjeldal, Frederik Ørsted; Hillers-Bendtsen, Andreas Erbs; Mikkelsen, Kurt V.; Olsen, Jeppe; Jørgensen, Poul.

I: Journal of Chemical Physics, Bind 157, Nr. 2, 024106, 2022.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Høyer, NM, Kjeldal, FØ, Hillers-Bendtsen, AE, Mikkelsen, KV, Olsen, J & Jørgensen, P 2022, 'Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian', Journal of Chemical Physics, bind 157, nr. 2, 024106. https://doi.org/10.1063/5.0082583

APA

Høyer, N. M., Kjeldal, F. Ø., Hillers-Bendtsen, A. E., Mikkelsen, K. V., Olsen, J., & Jørgensen, P. (2022). Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian. Journal of Chemical Physics, 157(2), [024106]. https://doi.org/10.1063/5.0082583

Vancouver

Høyer NM, Kjeldal FØ, Hillers-Bendtsen AE, Mikkelsen KV, Olsen J, Jørgensen P. Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian. Journal of Chemical Physics. 2022;157(2). 024106. https://doi.org/10.1063/5.0082583

Author

Høyer, Nicolai Machholdt ; Kjeldal, Frederik Ørsted ; Hillers-Bendtsen, Andreas Erbs ; Mikkelsen, Kurt V. ; Olsen, Jeppe ; Jørgensen, Poul. / Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian. I: Journal of Chemical Physics. 2022 ; Bind 157, Nr. 2.

Bibtex

@article{1c620aab6be84e0f8385428a5a335941,
title = "Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian",
abstract = "We have extended cluster perturbation (CP) theory to comprehend the Lagrangian framework of coupled cluster (CC) theory and derived the CP Lagrangian energy series (L-CP) where the 2n + 1/2n + 2 rules for the cluster amplitudes and multipliers are used to get the energy corrections. We have also developed the variational CP (LCP) series, where the total cluster amplitudes and multipliers are determined through the same orders as in the L-CP series, but the energy is obtained by inserting the total cluster amplitudes and multipliers in the Lagrangian. The energies of the LCP series have errors that are bilinear in the errors of the total cluster amplitudes and multipliers. Test calculations have been performed for S(D) and SD(T) orbital excitation spaces. With the exception of molecular systems that have a low lying doubly excited state compared to the electronic ground state configuration, we find that the fourth order models LCPS(D-4), LCPSD(T-4), and LCPSD(T-4) give energies of CC target state quality. For the LCPS(D-4) model, CC target state quality is obtained as the LCPS(D-4) calculation determines more than 99.7% of the coupled cluster singles and doubles (CCSD) correlation energy as the numerical deviations of the LCPS(D-4) energy from the CCSD energy were more than an order of magnitude smaller than the triples correlation contribution. For the LCPSD(T-4) and LCPSD(T-4) models, CC target state quality was obtained, given that the LCPSD(T-4) and LCPSD(T-4) calculations recover more than 99% of the coupled cluster singles doubles and triples (CCSDT) correlation contribution and as the numerical deviations of the LCPSD(T-4) and LCPSD(T-4) energies from the CCSDT energy were nearly and order of magnitude smaller than the quadruples correlation contribution. We, thus, suggest that the fourth order models may replace the full target CC models with no or very limited loss of accuracy. Published under an exclusive license by AIP Publishing.",
keywords = "RESPONSE FUNCTIONS, EXCITATION-ENERGIES, BASIS-SETS, 5TH-ORDER, SINGLES, FIELD",
author = "H{\o}yer, {Nicolai Machholdt} and Kjeldal, {Frederik {\O}rsted} and Hillers-Bendtsen, {Andreas Erbs} and Mikkelsen, {Kurt V.} and Jeppe Olsen and Poul J{\o}rgensen",
year = "2022",
doi = "10.1063/5.0082583",
language = "English",
volume = "157",
journal = "The Journal of Chemical Physics",
issn = "0021-9606",
publisher = "American Institute of Physics",
number = "2",

}

RIS

TY - JOUR

T1 - Cluster perturbation theory. VI. Ground-state energy series using the Lagrangian

AU - Høyer, Nicolai Machholdt

AU - Kjeldal, Frederik Ørsted

AU - Hillers-Bendtsen, Andreas Erbs

AU - Mikkelsen, Kurt V.

AU - Olsen, Jeppe

AU - Jørgensen, Poul

PY - 2022

Y1 - 2022

N2 - We have extended cluster perturbation (CP) theory to comprehend the Lagrangian framework of coupled cluster (CC) theory and derived the CP Lagrangian energy series (L-CP) where the 2n + 1/2n + 2 rules for the cluster amplitudes and multipliers are used to get the energy corrections. We have also developed the variational CP (LCP) series, where the total cluster amplitudes and multipliers are determined through the same orders as in the L-CP series, but the energy is obtained by inserting the total cluster amplitudes and multipliers in the Lagrangian. The energies of the LCP series have errors that are bilinear in the errors of the total cluster amplitudes and multipliers. Test calculations have been performed for S(D) and SD(T) orbital excitation spaces. With the exception of molecular systems that have a low lying doubly excited state compared to the electronic ground state configuration, we find that the fourth order models LCPS(D-4), LCPSD(T-4), and LCPSD(T-4) give energies of CC target state quality. For the LCPS(D-4) model, CC target state quality is obtained as the LCPS(D-4) calculation determines more than 99.7% of the coupled cluster singles and doubles (CCSD) correlation energy as the numerical deviations of the LCPS(D-4) energy from the CCSD energy were more than an order of magnitude smaller than the triples correlation contribution. For the LCPSD(T-4) and LCPSD(T-4) models, CC target state quality was obtained, given that the LCPSD(T-4) and LCPSD(T-4) calculations recover more than 99% of the coupled cluster singles doubles and triples (CCSDT) correlation contribution and as the numerical deviations of the LCPSD(T-4) and LCPSD(T-4) energies from the CCSDT energy were nearly and order of magnitude smaller than the quadruples correlation contribution. We, thus, suggest that the fourth order models may replace the full target CC models with no or very limited loss of accuracy. Published under an exclusive license by AIP Publishing.

AB - We have extended cluster perturbation (CP) theory to comprehend the Lagrangian framework of coupled cluster (CC) theory and derived the CP Lagrangian energy series (L-CP) where the 2n + 1/2n + 2 rules for the cluster amplitudes and multipliers are used to get the energy corrections. We have also developed the variational CP (LCP) series, where the total cluster amplitudes and multipliers are determined through the same orders as in the L-CP series, but the energy is obtained by inserting the total cluster amplitudes and multipliers in the Lagrangian. The energies of the LCP series have errors that are bilinear in the errors of the total cluster amplitudes and multipliers. Test calculations have been performed for S(D) and SD(T) orbital excitation spaces. With the exception of molecular systems that have a low lying doubly excited state compared to the electronic ground state configuration, we find that the fourth order models LCPS(D-4), LCPSD(T-4), and LCPSD(T-4) give energies of CC target state quality. For the LCPS(D-4) model, CC target state quality is obtained as the LCPS(D-4) calculation determines more than 99.7% of the coupled cluster singles and doubles (CCSD) correlation energy as the numerical deviations of the LCPS(D-4) energy from the CCSD energy were more than an order of magnitude smaller than the triples correlation contribution. For the LCPSD(T-4) and LCPSD(T-4) models, CC target state quality was obtained, given that the LCPSD(T-4) and LCPSD(T-4) calculations recover more than 99% of the coupled cluster singles doubles and triples (CCSDT) correlation contribution and as the numerical deviations of the LCPSD(T-4) and LCPSD(T-4) energies from the CCSDT energy were nearly and order of magnitude smaller than the quadruples correlation contribution. We, thus, suggest that the fourth order models may replace the full target CC models with no or very limited loss of accuracy. Published under an exclusive license by AIP Publishing.

KW - RESPONSE FUNCTIONS

KW - EXCITATION-ENERGIES

KW - BASIS-SETS

KW - 5TH-ORDER

KW - SINGLES

KW - FIELD

U2 - 10.1063/5.0082583

DO - 10.1063/5.0082583

M3 - Journal article

C2 - 35840396

VL - 157

JO - The Journal of Chemical Physics

JF - The Journal of Chemical Physics

SN - 0021-9606

IS - 2

M1 - 024106

ER -

ID: 315170002