Challenging the electrostatic <i>σ</i>‐hole picture of halogen bonding using minimal models and the interacting quantum atoms approach

Jiménez‐Grávalos, Fernando; Gallegos, Miguel; Pendás, Ángel Martín; Novikov, Alexander S.

doi:10.1002/jcc.26488

Cited by 22 publications

(19 citation statements)

References 84 publications

(110 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Among the established concepts on noncovalent intermolecular interactions, the σ‐hole model and its implications have been controversially discussed in recent years, especially in the context of halogen bonding [42–44] . While all studies agree on the fact that a depletion of electron density opposite of a sigma bond leads to a fairly strong interaction that is strongly directional, [45,46] different analysis tools indicate that it could either be regarded as electrostatic or as charge‐transfer including orbital interactions [47] . For the interaction of heavy pnictogen atoms and the π‐system, as discussed in ref.…”

Section: Resultsmentioning

confidence: 99%

“…[ 42 , 43 , 44 ] While all studies agree on the fact that a depletion of electron density opposite of a sigma bond leads to a fairly strong interaction that is strongly directional,[ 45 , 46 ] different analysis tools indicate that it could either be regarded as electrostatic or as charge‐transfer including orbital interactions. [47] For the interaction of heavy pnictogen atoms and the π‐system, as discussed in ref. [10] , a thorough analysis of the angle‐dependance of the interaction energies, however, showed that the potential energy surfaces appear very flat.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Are Heavy Pnictogen‐π Interactions Really “π Interactions”?

Schiavo

Bhattacharyya

Mehring

et al. 2021

Chemistry A European J

View full text Add to dashboard Cite

The noncovalent interactions of heavy pnictogens with π‐arenes play a fundamental role in fields like crystal engineering or catalysis. The strength of such bonds is based on an interplay between dispersion and donor/acceptor interactions, and is generally attributed to the presence of π‐arenes. Computational studies of the interaction between the heavy pnictogens As, Sb and Bi and cyclohexane, in comparison with previous studies on the interaction between heavy pnictogens and benzene, show that this concept probably has to be revised. A thorough analysis of all the different energetic components that play a role in these systems, carried out with state‐of‐the‐art computational methods, sheds light on how they influence one another and the effect that their interplay has on the overall system. Furthermore, the analysis of such interactions leads us to the unexpected finding that the presence of the pnictogen compounds strongly affects the conformational equilibrium of cyclohexane, reversing the relative stability of the chair and boat‐twist conformers, and thus suggesting a possible application of tuneable dispersion energy donors to stabilise the desired conformation.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Are Heavy Pnictogen‐π Interactions Really “π Interactions”?

Schiavo

Bhattacharyya

Mehring

et al. 2021

Chemistry A European J

View full text Add to dashboard Cite

show abstract

“…Brinck and Borrfors studied a series of halogen bonded complexes (R–Br···Br – and R′–CC–Br···Br – where R is a substituted methyl group) and showed that the halogen-bonding strength correlates linearly with the interaction energy from a point-charge model by replacing Br – with a point charge. Subsequently, they concluded that “the halogen bond can be described accurately by electrostatics and polarization without any need to consider charge transfer.” But there have been negative correlations between maximum electrostatic potentials and interaction energies even when polarization is considered in the literature. , In fact, there have been profound theoretical and experimental studies, including ours, confirming the crucial or even dominating role of charge transfer interaction in halogen bonding. − For instance, Wolter and Bickelhaupt compared the halogen bonding in D–X···A – and hydrogen bonding in D–H···A – (D, X, and A are halogen elements) and found that apart from the classical electrostatic attraction, there is substantial HOMO–LUMO interactions between the lone pair of A and the σ* orbital of the D–X or D–H bond . In other words, there is considerable charge transfer interactions from A – to D–X/D–H in both types of bonding.…”

Section: Introductionmentioning

confidence: 81%

Role of Charge Transfer in Halogen Bonding

Inscoe

Rathnayake

2021

J. Phys. Chem. A

View full text Add to dashboard Cite

Halogen bonding has received intensive attention recently for its applications in the construction of supramolecular assemblies and crystal engineering and its implications and potentials in chemical and biological processes and rational drug design. Peculiarly, in intermolecular interactions, halogen atoms are known as electron-donating groups carrying partial negative charges in molecules due to its high electronegativity, but they can counterintuitively act as Lewis acids and bind with Lewis bases in the form of a halogen bond. The unsettling issue regarding the nature of the halogen bonding is whether the electrostatics or charge transfer interaction dominates. The recently proposed σ-hole concept nicely reinforces the role of electrostatic attraction. Also, good correlations between the halogen bonding strength and the interaction energy from the simple point-charge model have been found. This leads to the claim that there is no need to invoke the charge transfer concept in the halogen bond. But there is alternative evidence supporting the importance of charge transfer interaction. Here, we visited a series of prominent halogen bonded complexes of the types Y 3 C−X•••Z (X = Br, I; Y = F, Cl, Br; Z = F − , Cl − , Br − , I − , NMe 3 ) with the block-localized wave function (BLW) method at the M06-2X-D3/6-311+G(d,p) (def2-SVP for iodine) level of theory. As the simplest variant of ab initio valence bond (VB) theory, the BLW method is unique in the strict localization of electrons within interacting moieties, allowing for quantitative evaluation of the charge transfer effect on geometries, spectral properties, and energetics in halogen bonding complexes. By comparing the halogen bonding complexes with and without the charge transfer interaction, we proved that the charge transfer interaction significantly shortens the X•••Z bonding distance and stretches the C−X bonds. But the shortening of the halogen bonding results in the less favorable steric effect, which is composed of Pauli repulsion, electrostatics, and electron correlation. There are approximate linear correlations between the charge transfer effect and binding energy and between bonding distance and binding energy. These correlations may lead to the illusion that the charge transfer interaction is unimportant or irrelevant, but further analyses showed that the inclusion of charge transfer is critical for the proper description of the halogen bonding, as considering only electrostatics and polarization leads to only about 45−60% of the binding strengths and much elongated bonding distances.

show abstract

“…In an octameric synthon, the Although the electrostatic model continues to be useful in rationalizing the halogen bonding, 111 our results support the need to consider the weak nonelectrostatic interactions for this purpose. 42,112…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…Albeit the presence of σ-holes, the Br···Br interactions present in the synthons have destabilizing or nearly zero Coulombic components according to the IQA analysis. Although the electrostatic model continues to be useful in rationalizing the halogen bonding, our results support the need to consider the weak nonelectrostatic interactions for this purpose. , …”

Section: Resultsmentioning

confidence: 99%

Giant Supramolecular Synthons via Cyclic Halogen···Halogen Contacts in Substituted o-Xylenes

Nair

Prasad

Babu

et al. 2022

Crystal Growth & Design

View full text Add to dashboard Cite

Architecting unique supramolecular structures requires robust and reproducible supramolecular synthons. Noncovalent halogen bonding offers rich crystal packing possibilities through diverse synthons and thus constitutes a useful structural domain in crystal groups. The variations in halogen synthon patterns with bromine substitution was explored by means of crystal packing analyses of a series of brominesubstituted o-xylenes. We report an unprecedented giant cyclic supramolecular Br 8 synthon with a fused triangular prism-like geometry formed exclusively through hypervalent Br•••Br interactions in the crystal structure of α,α,α′,α′-tetrabromo-o-xylene. A new polymorph of the compound α,α,α′,α′-tetrabromo-o-xylene with a Br 4 tetrahedral synthon was isolated and characterized by single-crystal X-ray diffraction. Additionally, a rectangular Br 4 synthon was found to direct the crystal packing in α,α,α′-tribromo-o-xylene. Lines of evidence for the noncovalent intermolecular Br•••Br interactions rendering the Br 8 and the Br 4 synthons were quantitatively obtained by Bader's quantum theory of atoms in molecules (QTAIM). Noncovalent interaction index isosurfaces exposed the intramolecular interactions, which were not evident from QTAIM. Penda's interacting quantum atom energy partitioning provided insight into the Br•••Br interaction energy in terms of electrostatic and exchange−correlation components. Despite the presence of σ holes as characterized by electrostatic potential analysis, the Br•••Br interactions constituting the Br 8 and Br 4 synthons are stabilized through nonelectrostatic components. The current study intends to reinforce the potential of nonelectrostatic weak halogen•••halogen contacts to give rise to a wide variety of synthon patterns and develop solid supramolecular assemblies that find applications in numerous fields of research.

show abstract

Challenging the electrostatic σ‐hole picture of halogen bonding using minimal models and the interacting quantum atoms approach

Cited by 22 publications

References 84 publications

Are Heavy Pnictogen‐π Interactions Really “π Interactions”?

Are Heavy Pnictogen‐π Interactions Really “π Interactions”?

Role of Charge Transfer in Halogen Bonding

Giant Supramolecular Synthons via Cyclic Halogen···Halogen Contacts in Substituted o-Xylenes

Contact Info

Product

Resources

About