Kinetic Energy Density as a Predictor of Hydrogen-Bonded OH-Stretching Frequencies

Lane, Joseph R.; Hansen, Anne S.; Mackeprang, Kasper; Kjaergaard, Henrik G.

doi:10.1021/acs.jpca.7b02523

Cited by 26 publications

(40 citation statements)

References 55 publications

(159 reference statements)

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“…A necessary condition is the existence of a bond path and a bcp between the two atoms under consideration; a sufficient condition is a negative value of the local energy density H(r) = V(r) + G(r) at the bcp, which implies a dominating potential energy V(r) (always negative, stabilizing) over the kinetic energy G(r) (always positive, destabilizing), and is indicative of a covalent interaction. These signatures are not only true for hydrogen bonds [252], but also for halogen bonds, tetrel bonds, chalcogen bonds, pnictogen bonds, and any other noncovalent interaction, and including metal-ligand coordinate interactions of various types [253,254].…”

Section: Charge Density Models For Visualizing Noncovalent Interactionsmentioning

confidence: 99%

Halogen Bonding: A Halogen-Centered Noncovalent Interaction Yet to Be Understood

2019

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In addition to the underlying basic concepts and early recognition of halogen bonding, this paper reviews the conflicting views that consistently appear in the area of noncovalent interactions and the ability of covalently bonded halogen atoms in molecules to participate in noncovalent interactions that contribute to packing in the solid-state. It may be relatively straightforward to identify Type-II halogen bonding between atoms using the conceptual framework of σ-hole theory, especially when the interaction is linear and is formed between the axial positive region (σ-hole) on the halogen in one monomer and a negative site on a second interacting monomer. A σ-hole is an electron density deficient region on the halogen atom X opposite to the R–X covalent bond, where R is the remainder part of the molecule. However, it is not trivial to do so when secondary interactions are involved as the directionality of the interaction is significantly affected. We show, by providing some specific examples, that halogen bonds do not always follow the strict Type-II topology, and the occurrence of Type-I and -III halogen-centered contacts in crystals is very difficult to predict. In many instances, Type-I halogen-centered contacts appear simultaneously with Type-II halogen bonds. We employed the Independent Gradient Model, a recently proposed electron density approach for probing strong and weak interactions in molecular domains, to show that this is a very useful tool in unraveling the chemistry of halogen-assisted noncovalent interactions, especially in the weak bonding regime. Wherever possible, we have attempted to connect some of these results with those reported previously. Though useful for studying interactions of reasonable strength, IUPAC’s proposed “less than the sum of the van der Waals radii” criterion should not always be assumed as a necessary and sufficient feature to reveal weakly bound interactions, since in many crystals the attractive interaction happens to occur between the midpoint of a bond, or the junction region, and a positive or negative site.

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Section: Charge Density Models For Visualizing Noncovalent Interactionsmentioning

confidence: 99%

Halogen Bonding: A Halogen-Centered Noncovalent Interaction Yet to Be Understood

2019

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“…The most common real-space method, the Quantum Theory of Atoms in Molecules (QTAIM) (Matta & Boyd, 2007), provides an opportunity to explore bonding diatomic interactions with meaningful exchange energy contributions and subsequently to construct the atomic connectivity graph. The properties of corresponding descriptors of topological bonding, such as interatomic surfaces and (3, À1) critical points (CPs) of electron density (r), serve as weights of the connectivity graph and are frequently used to provide a range diatomic interactions in terms of charge separation and contributions to the energy of the system (Bader & Essé n, 1984;Cremer & Kraka, 1984;Silva Lopez & de Lera, 2011;Alkorta et al, 1998;Espinosa et al, 1998;Vener et al, 2012;Bartashevich, Matveychuk et al, 2014;Saleh et al, 2015;Lane et al, 2017;Ananyev et al, 2017;Borissova et al, 2008;Romanova et al, 2018). For instance, the topographic analysis of (r) in the transition metal complexes usually indicates the MÁ Á ÁX bonding interaction for any coordination bond, i.e.…”

Section: Resultsmentioning

confidence: 99%

Structure-directing sulfur...metal noncovalent semicoordination bonding

Ananyev¹,

Bokach²,

Kukushkin³

2020

Acta Crystallogr Sect B

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The abundance and geometric features of nonbonding contacts between metal centers and 'soft' sulfur atoms bound to a non-metal substituent R were analyzed by processing data from the Cambridge Structural Database. The angular arrangement of M, S and R atoms with /(R-SÁ Á ÁM) down to 150 was a common feature of the late transition metal complexes exhibiting shortened R-SÁ Á ÁM contacts. Several model nickel(II), palladium(II), platinum(II) and gold(I) complexes were chosen for a theoretical analysis of R-SÁ Á ÁM interactions using the DFT method applied to (equilibrium) isolated systems. A combination of the real-space approaches, such as Quantum Theory of Atoms in Molecules (QTAIM), noncovalent interaction index (NCI), electron localization function (ELF) and Interacting Quantum Atoms (IQA), and orbital (Natural Bond Orbitals, NBO) methods was used to provide insights into the nature and energetics of R-SÁ Á ÁM interactions with respect to the metal atom identity and its coordination environment. The explored features of the R-SÁ Á ÁM interactions support the trends observed by inspecting the CSD statistics, and indicate a predominant contribution of semicoordination bonds between nucleophilic sites of the sulfur atom and electrophilic sites of the metal. A contribution of chalcogen bonding (that is formally opposite to semicoordination) was also recognized, although it was significantly smaller in magnitude. The analysis of R-SÁ Á ÁM interaction strengths was performed and the structure-directing role of the intramolecular R-SÁ Á ÁM interactions in stabilizing certain conformations of metal complexes was revealed. research papers Acta Cryst. (2020). B76, 436-449 Ananyev et al. Structure-directing SÁ Á ÁM noncovalent semicoordination bonding 437 Figure 1Electrophilic (two -holes in blue) and nucleophilic sites (two LPs in red) in ChR 2 ; formation of a noncovalent contact (SB or HB) with an electrophile and noncovalent contact (ChB) with a nucleophile. The idealized angles are shown for both types of contacts.

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“…), the E B ∼ g ( r bcp ) correlation ( g ( r bcp ) denotes Lagrangian electronic kinetic energy density at bcp ) established for hydrogen bonds and further extended on a wider range of noncovalent interactions (see, ref. ), the Δ ν ∼ g ( r ) RDG correlation (RDG—reduced density gradient, g ( r ) RDG denotes integral of electronic kinetic energy density within a specific isosurface of the RDG function, Δ ν —shift of a vibration band upon the interaction formation/breaking) for hydrogen bonds, the E B ∼ v ( r ) RDG and E B ∼ g ( r ) RDG correlations for various weak interactions …”

Section: Resultsmentioning

confidence: 99%

“…Each E B ∼ ρ ( r bcp ) correlation was developed for a particular interaction type, for which it is known that the ρ ( r bcp ) and v ( r bcp ) values are interconnected and depend only on internuclear separation. Moreover, if it is believed that the local quantity at bcp is a measure of the integral of this quantity over the region around this bcp , than the Δ ν ∼ g ( r ) RDG , E B ∼ g ( r ) RDG and E B ∼ v ( r ) RDG correlations can also be considered as special cases of the general k eff

\sim {false\iint}_{I A S}^{} v (|, boldr) normald boldr

trend. Again, the v ( r ) and g ( r ) values are interconnected through the local virial theorem, while the red shifts of the XH stretching vibrational frequency are nearly quantitatively equal to changes of the XH stretching force constant since the reduced mass of the XH stretching vibration is close to unity (for instance for X = O μ ≈ 0.94 a.m.u.)…”

Section: Resultsmentioning

confidence: 99%

“…This kind of analysis is also attractive as the ρ ( r ) function can readily be calculated using wavefunction or density functional theories or even can be constructed from experimental diffraction data from long‐ordered solids such as crystals . Various features, which can be calculated at bcp and around it, are usually analyzed to describe an interaction in terms of its ionic/covalent character, directionality and finally, strength …”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Estimations of energy of noncovalent bonding from integrals over interatomic zero‐flux surfaces: Correlation trends and beyond

Romanova

Ananyev

2018

J Comput Chem

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Bonding energies of 50 associates composed by neutral molecules (atoms) and bounded by various weak noncovalent interactions are calculated within the DFT framework using the PBE0/aug-cc-pVTZ combination. The electronic virial and electron density values at bond critical points together with their integrals over interatomic surfaces are tested to check their ability to estimate bonding energies. Two correlations schemes dealing with integrals over interatomic surface are suggested to estimate bonding energy of any noncovalent interaction. The physical meaning of explored and several known correlations is discussed. Methods to estimate interatomic surface integrals of electronic virial and electron density are proposed. © 2018 Wiley Periodicals, Inc.

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Kinetic Energy Density as a Predictor of Hydrogen-Bonded OH-Stretching Frequencies

Cited by 26 publications

References 55 publications

Halogen Bonding: A Halogen-Centered Noncovalent Interaction Yet to Be Understood

Halogen Bonding: A Halogen-Centered Noncovalent Interaction Yet to Be Understood

Structure-directing sulfur...metal noncovalent semicoordination bonding

Estimations of energy of noncovalent bonding from integrals over interatomic zero‐flux surfaces: Correlation trends and beyond

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