Range-Separated meta-GGA Functional Designed for Noncovalent Interactions

Range-Separated meta-GGA Functional Designed for Noncovalent Interactions

The accuracy of applying density functional theory to noncovalent interactions is hindered by errors arising from low-density regions of interaction-induced change in the density gradient, error compensation between correlation and exchange functionals, and dispersion double counting. A new exchange...

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Bibliographic Details
Published in:Journal of chemical theory and computation Vol. 10; no. 10; pp. 4297 - 4306
Main Authors: Modrzejewski, Marcin, Chałasiński, Grzegorz, Szczęśniak, Małgorzata M
Format: Journal Article
Language:English
Published: United States American Chemical Society 14-10-2014
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Summary:The accuracy of applying density functional theory to noncovalent interactions is hindered by errors arising from low-density regions of interaction-induced change in the density gradient, error compensation between correlation and exchange functionals, and dispersion double counting. A new exchange–correlation functional designed for noncovalent interactions is proposed to address these problems. The functional consists of the range-separated PBEsol exchange considered in two variants, pure and hybrid, and the semilocal correlation functional of Modrzejewski et al. (J. Chem. Phys. 2012, 137, 204121) designed with the constraint satisfaction technique to smoothly connect with a dispersion term. Two variants of dispersion correction are appended to the correlation functional: the atom–atom pairwise additive DFT-D3 model and the density-dependent many-body dispersion with self-consistent screening (MBD-rsSCS). From these building blocks, a set of four functionals is created to systematically examine the role of pure versus hybrid exchange and the underlying models for dispersion. The new functional is extensively tested on benchmark sets with diverse nature and size. Truly outstanding performance is demonstrated for water clusters of varying size, ionic hydrogen bonds, and thermochemistry of isodesmic n-alkane fragmentation reactions. The merits of each component of the new functional are discussed.
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ISSN:1549-9618
1549-9626
DOI:10.1021/ct500707w