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Main Authors: Teke, Nakul, Melekamburath, Ajay, Gaudel, Bimal, Valeev, Edward F.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.08859
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author Teke, Nakul
Melekamburath, Ajay
Gaudel, Bimal
Valeev, Edward F.
author_facet Teke, Nakul
Melekamburath, Ajay
Gaudel, Bimal
Valeev, Edward F.
contents To follow up on the unexpectedly-good performance of several coupled-cluster models with approximate inclusion of 3-body clusters [J. Chem. Phys. 151, 064102 (2019)] we performed a more complete assessment of the 3CC method [J. Chem. Phys. 125, 204105 (2006)] for accurate computational thermochemistry in the standard HEAT framework. New spin-integrated implementation of the 3CC method applicable to closed- and open-shell systems utilizes a new automated toolchain for derivation, optimization, and evaluation of operator algebra in many-body electronic structure. We found that with a double-zeta basis set the 3CC correlation energies and their atomization energy contributions are almost always more accurate (with respect to the CCSDTQ reference) than the CCSDT model as well as the standard CCSD(T) model. The mean absolute errors in cc-pVDZ {3CC, CCSDT, and CCSD(T)} electronic (per valence electron) and atomization energies relative to the CCSDTQ reference for the HEAT dataset [J. Chem. Phys. 121, 11599 (2004)], were {24, 70, 122} $μE_h/e$ and {0.46, 2.00, 2.58} kJ/mol, respectively. The mean absolute errors in the complete-basis-set limit {3CC, CCSDT, and CCSD(T)} atomization energies relative to the HEAT model reference, were {0.52, 2.00, and 1.07} kJ/mol, The significant and systematic reduction of the error by the 3CC method and its lower cost than CCSDT suggests it as a viable candidate for post-CCSD(T) thermochemistry applications, as well as the preferred alternative to CCSDT in general.
format Preprint
id arxiv_https___arxiv_org_abs_2407_08859
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle "Best" iterative coupled-cluster triples model: More evidence for 3CC
Teke, Nakul
Melekamburath, Ajay
Gaudel, Bimal
Valeev, Edward F.
Chemical Physics
To follow up on the unexpectedly-good performance of several coupled-cluster models with approximate inclusion of 3-body clusters [J. Chem. Phys. 151, 064102 (2019)] we performed a more complete assessment of the 3CC method [J. Chem. Phys. 125, 204105 (2006)] for accurate computational thermochemistry in the standard HEAT framework. New spin-integrated implementation of the 3CC method applicable to closed- and open-shell systems utilizes a new automated toolchain for derivation, optimization, and evaluation of operator algebra in many-body electronic structure. We found that with a double-zeta basis set the 3CC correlation energies and their atomization energy contributions are almost always more accurate (with respect to the CCSDTQ reference) than the CCSDT model as well as the standard CCSD(T) model. The mean absolute errors in cc-pVDZ {3CC, CCSDT, and CCSD(T)} electronic (per valence electron) and atomization energies relative to the CCSDTQ reference for the HEAT dataset [J. Chem. Phys. 121, 11599 (2004)], were {24, 70, 122} $μE_h/e$ and {0.46, 2.00, 2.58} kJ/mol, respectively. The mean absolute errors in the complete-basis-set limit {3CC, CCSDT, and CCSD(T)} atomization energies relative to the HEAT model reference, were {0.52, 2.00, and 1.07} kJ/mol, The significant and systematic reduction of the error by the 3CC method and its lower cost than CCSDT suggests it as a viable candidate for post-CCSD(T) thermochemistry applications, as well as the preferred alternative to CCSDT in general.
title "Best" iterative coupled-cluster triples model: More evidence for 3CC
topic Chemical Physics
url https://arxiv.org/abs/2407.08859