Non-iterative doubles corrections to the random phase and higher random phase approximations: singlet and triplet excitation energies

Pi Ariane Bresling Haase; Rasmus Faber; Patricio F. Provasi; Stephan P. A. Sauer

doi:10.1002/jcc.26074

Non-iterative doubles corrections to the random phase and higher random phase approximations: singlet and triplet excitation energies

Pi Ariane Bresling Haase, Rasmus Faber, Patricio F. Provasi, Stephan P. A. Sauer

Department of Chemistry

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Abstract

The second-order noniterative doubles-corrected random phase approximation (RPA) method has been extended to triplet excitation energies and the doubles-corrected higher RPA method as well as a shifted version for calculating singlet and triplet excitation energies are presented here for the first time. A benchmark set consisting of 20 molecules with a total of 117 singlet and 71 triplet excited states has been used to test the performance of the new methods by comparison with previous results obtained with the second-order polarization propagator approximation (SOPPA) and the third order approximate coupled cluster singles, doubles and triples model CC3. In general, the second-order doubles corrections to RPA and HRPA significantly reduce both the mean deviation as well as the standard deviation of the errors compared to the CC3 results. The accuracy of the new methods approaches the accuracy of the SOPPA method while using only 10–60% of the calculation time.

Original language	English
Journal	Journal of Computational Chemistry
Volume	41
Issue number	1
Pages (from-to)	43-55
Number of pages	13
ISSN	0192-8651
DOIs	https://doi.org/10.1002/jcc.26074
Publication status	Published - 5 Jan 2020

Keywords

Faculty of Science
RPA(D)
HRPA(D)
Excitation Energy
SOPPA
Quantum Chemistry
Computational Chemistry

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Noniterative Doubles Corrections to the Random Phase and Higher Random Phase ApproximationsFinal published version, 1.56 MBLicence: CC BY

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Non-iterative doubles corrections to the random phase and higher random phase approximations : singlet and triplet excitation energies. / Haase, Pi Ariane Bresling; Faber, Rasmus; Provasi, Patricio F. et al.

In: Journal of Computational Chemistry, Vol. 41, No. 1, 05.01.2020, p. 43-55.

Research output: Contribution to journal › Journal article › Research › peer-review

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abstract = "The second-order noniterative doubles-corrected random phase approximation (RPA) method has been extended to triplet excitation energies and the doubles-corrected higher RPA method as well as a shifted version for calculating singlet and triplet excitation energies are presented here for the first time. A benchmark set consisting of 20 molecules with a total of 117 singlet and 71 triplet excited states has been used to test the performance of the new methods by comparison with previous results obtained with the second-order polarization propagator approximation (SOPPA) and the third order approximate coupled cluster singles, doubles and triples model CC3. In general, the second-order doubles corrections to RPA and HRPA significantly reduce both the mean deviation as well as the standard deviation of the errors compared to the CC3 results. The accuracy of the new methods approaches the accuracy of the SOPPA method while using only 10–60% of the calculation time.",

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AU - Haase, Pi Ariane Bresling

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AU - Provasi, Patricio F.

AU - Sauer, Stephan P. A.

PY - 2020/1/5

Y1 - 2020/1/5

N2 - The second-order noniterative doubles-corrected random phase approximation (RPA) method has been extended to triplet excitation energies and the doubles-corrected higher RPA method as well as a shifted version for calculating singlet and triplet excitation energies are presented here for the first time. A benchmark set consisting of 20 molecules with a total of 117 singlet and 71 triplet excited states has been used to test the performance of the new methods by comparison with previous results obtained with the second-order polarization propagator approximation (SOPPA) and the third order approximate coupled cluster singles, doubles and triples model CC3. In general, the second-order doubles corrections to RPA and HRPA significantly reduce both the mean deviation as well as the standard deviation of the errors compared to the CC3 results. The accuracy of the new methods approaches the accuracy of the SOPPA method while using only 10–60% of the calculation time.

AB - The second-order noniterative doubles-corrected random phase approximation (RPA) method has been extended to triplet excitation energies and the doubles-corrected higher RPA method as well as a shifted version for calculating singlet and triplet excitation energies are presented here for the first time. A benchmark set consisting of 20 molecules with a total of 117 singlet and 71 triplet excited states has been used to test the performance of the new methods by comparison with previous results obtained with the second-order polarization propagator approximation (SOPPA) and the third order approximate coupled cluster singles, doubles and triples model CC3. In general, the second-order doubles corrections to RPA and HRPA significantly reduce both the mean deviation as well as the standard deviation of the errors compared to the CC3 results. The accuracy of the new methods approaches the accuracy of the SOPPA method while using only 10–60% of the calculation time.

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Non-iterative doubles corrections to the random phase and higher random phase approximations: singlet and triplet excitation energies

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