Understanding non-covalent interactions in larger molecular complexes from first principles

Al-Hamdani, Yasmine S.; Tkatchenko, Alexandre

doi:10.1063/1.5075487

Cited by 78 publications

(151 citation statements)

References 186 publications

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“…An important example of such a benchmark SAPT(DFT) study is the calculation of interaction energies for the S12L database of large complexes . For systems of this size, a computation of unambiguous benchmark values exceeds our current algorithmic and computational capabilities, and the original S12L benchmark data (obtained by back‐correcting experimental association free energies) as well as high‐level local CC and quantum Monte Carlo interaction energies differ by up to several kcal/mol . In this case, it is highly advantageous to have other data available that combine reasonable accuracy with physical insight via the SAPT(DFT) energy decomposition.…”

Section: The Sapt Formalismmentioning

confidence: 99%

“…Noncovalent interactions are not only ubiquitous, but they are also absolutely necessary to describe many physical, chemical, and biochemical phenomena, ranging from thermodynamics of nonideal gases to spectroscopy and scattering cross sections of interstellar complexes to the performance and selectivity (including enantioselectivity) of molecular catalysts to the secondary, tertiary, and quaternary structure of proteins, the double‐helix structure of DNA, and the interaction between enzymes and their substrates (or inhibitors). Thus, theoretical and experimental investigations of noncovalent interactions are published in very large quantities, and various aspects of these interactions have been reviewed in this journal and elsewhere …”

Section: Introductionmentioning

confidence: 99%

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Recent developments in symmetry‐adapted perturbation theory

Patkowski

2019

WIREs Comput Mol Sci

147

144

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Symmetry-adapted perturbation theory (SAPT) is a well-established method to compute accurate intermolecular interaction energies in terms of physical effects such as electrostatics, induction (polarization), dispersion, and exchange. With many theory levels and variants, and several computer implementations available, closed-shell SAPT has been applied to produce numerous intermolecular potential energy surfaces for complexes of experimental interest, and to elucidate the interactions in various complexes relevant to catalysis, organic synthesis, and biochemistry. In contrast, the development of SAPT for general open-shell complexes is still a work in progress. In the last decade, new developments from several research groups, including the author's, have greatly enhanced the capabilities of SAPT. The new and emerging approaches are designed to make SAPT more widely applicable (including interactions involving multireference systems, complexes in arbitrary spin states, and intramolecular noncovalent interactions), more accurate (enhanced description of intramolecular correlation, a better account of exchange effects, relativistic SAPT, and explicitly correlated SAPT), and more efficient (enhanced density-fitted implementations, linearscaling variants, empirical dispersion, and an implementation on graphics processing units).The new developments open up avenues for SAPT applications to an unprecedented variety of weakly interacting complexes.

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Section: The Sapt Formalismmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Recent developments in symmetry‐adapted perturbation theory

Patkowski

2019

WIREs Comput Mol Sci

147

144

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“…As a note of caution, one should be aware that the remarkable accuracy achieved by dispersion‐corrected mean field approaches for standard benchmark sets is the result of careful parametrization using available high quality benchmark values on relatively small systems, typically obtained from accurate first principles calculations. Such methods include the “gold standard” CCSD(T) and its local variants as well as Quantum Monte Carlo approaches …”

Section: Mean‐field Approachesmentioning

confidence: 99%

“…On the other hand, their main limitation is the heavy reliance on benchmark studies for parametrizing, assessing the accuracy and in some cases re‐parametrizing the exchange‐correlation functional. Considering that the large majority of reliable benchmark studies for NCIs focus on small systems with a few tens of atoms, one might question the reliability of these methods on computational predictions for large systems . Fortunately, with the development of fast and accurate first principles methods like the modern local CCSD(T) variants, it is becoming possible to put these methods to a quantitative test for large systems …”

Section: Mean‐field Approachesmentioning

confidence: 99%

Finding chemical concepts in the Hilbert space: Coupled cluster analyses of noncovalent interactions

Bistoni

2019

WIREs Comput Mol Sci

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Noncovalent interactions (NCIs) play a major role in essentially all fields of chemical research. Energy decomposition analysis (EDA) schemes provide in-depth insights into their nature by decomposing interaction energies into additive contributions, such as electrostatics, polarization, and London dispersion. Although modern local variants of the "gold standard" coupled-cluster singles and doubles method plus perturbative triples (CCSD(T)) have made it possible to accurately quantify NCIs for relatively large systems, extracting chemically meaningful energy terms from such high level electronic structure calculations has been a long lasting challenge in computational chemistry. This review describes basic principles, interpretative aspects and applications of recently developed coupled clusterbased EDAs for the analysis of NCIs. The focus is on computationally efficient methods for systems with a few hundred atoms, for example, the recently introduced local energy decomposition analysis. In order to draw connections between different interpretative frameworks, these schemes are compared with other popular approaches for the quantification and analysis of NCIs, such as Symmetry Adapted Perturbation Theory and supermolecular EDAs based on mean-field as well as correlated approaches. Strengths and limitations of the various techniques are discussed. This article is characterized under: Electronic Structure Theory > Ab Initio Electronic Structure Methods Structure and Mechanism > Molecular Structures K E Y W O R D S coupled cluster, energy decomposition analysis, local correlation, local energy decomposition, London dispersion 1 | INTRODUCTIONNoncovalent interactions (NCIs), that is, attractive or repulsive forces between non-bonded atoms or molecules, are ubiquitous in chemistry. For instance, they determine the selectivity of asymmetric transformations, the formation and structure of prereactive intermediates, the folding of proteins, the structure of molecular systems in the gas and condensed phases.

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“…For the DLPNO‐MP2 and DLPNO‐CCSD(T/T0) calculations for the study of noncovalent systems, it is necessary to use the tight PNO thresholds because the LoosePNO settings and even the NormalPNO settings maybe exclude the weakly interacting electronic states which play important roles in the correlation energy calculations of the noncovalent systems . For the isolated DLPNO‐MP2 or DLPNO‐CCSD(T/T0) calculations, the case is simple and just use the recommended tight PNO thresholds or even the very tight PNO thresholds.…”

Section: Resultsmentioning

confidence: 99%

Toward a less costly but accurate calculation of the CCSD(T)/CBS noncovalent interaction energy

et al. 2020

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The popular method of calculating the noncovalent interaction energies at the coupled-cluster single-, double-, and perturbative triple-excitations [CCSD(T)] theory level in the complete basis set (CBS) limit was to add a CCSD(T) correction term to the CBS second-order Møller-Plesset perturbation theory (MP2). The CCSD(T) correction term is the difference between the CCSD(T) and MP2 interaction energies evaluated in a medium basis set. However, the CCSD(T) calculations with the medium basis sets are still very expensive for systems with more than 30 atoms. Comparatively, the domain-based local pair natural orbital coupled-cluster method [DLPNO-CCSD(T)] can be applied to large systems with over 1,000 atoms. Considering both the computational accuracy and efficiency, in this work, we propose a new scheme to calculate the CCSD(T)/CBS interaction energies. In this scheme, the MP2/CBS term keeps intact and the CCSD(T) correction term is replaced by a DLPNO-CCSD (T) correction term which is the difference between the DLPNO-CCSD(T) and DLPNO-MP2 interaction energies evaluated in a medium basis set. The interaction energies of the noncovalent systems in the S22, HSG, HBC6, NBC10, and S66 databases were recalculated employing this new scheme. The consistent and tight settings of the truncation parameters for DLPNO-CCSD(T) and DLPNO-MP2 in this noncanonical CCSD(T)/CBS calculations lead to the maximum absolute deviation and root-mean-square deviation from the canonical CCSD(T)/CBS interaction energies of less than or equal to 0.28 kcal/mol and 0.09 kcal/mol, respectively. The high accuracy and low cost of this new computational scheme make it an excellent candidate for the study of large noncovalent systems.

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Understanding non-covalent interactions in larger molecular complexes from first principles

Cited by 78 publications

References 186 publications

Recent developments in symmetry‐adapted perturbation theory

Recent developments in symmetry‐adapted perturbation theory

Finding chemical concepts in the Hilbert space: Coupled cluster analyses of noncovalent interactions

Toward a less costly but accurate calculation of the CCSD(T)/CBS noncovalent interaction energy

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