Fluorines in tetrafluoromethane as halogen bond donors: Revisiting address the nature of the fluorine's<i>σ</i><sub>hole</sub>

Varadwaj, Pradeep R.; Jin, Bih‐Yaw

doi:10.1002/qua.24877

Cited by 49 publications

(107 citation statements)

References 144 publications

(71 reference statements)

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“…Since the pioneering work by Brinck et al, many studies have used molecular electrostatic potential maps to demonstrate the σ‐hole in possible halogen‐bond donors, see for example references . Figure shows the electrostatic potential surfaces of the halogenated methyluracil molecules studied in this work.…”

Section: Resultsmentioning

confidence: 99%

“…This has been attributed to the high electronegativity of fluorine and its tendency to engage in significant sp hybridization, which produces an influx of negative charge into the region where the positive σ‐hole would be . Some recent studies state that organic fluorines can form halogen bonds when strongly electronegative substituents are bound to the carbon . However, it has been suggested that this type of bond should not be labelled a halogen bond, as there are fundamental differences between these interactions and halogen bonds involving Cl, Br, and I .…”

Section: Introductionmentioning

confidence: 99%

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Competition between hydrogen and halogen bonding in halogenated 1‐methyluracil: Water systems

Hogan

Mourik

2016

J Comput Chem

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The competition between hydrogen‐ and halogen‐bonding interactions in complexes of 5‐halogenated 1‐methyluracil (XmU; X = F, Cl, Br, I, or At) with one or two water molecules in the binding region between C5‐X and C4O4 is investigated with M06‐2X/6‐31+G(d). In the singly‐hydrated systems, the water molecule forms a hydrogen bond with C4O4 for all halogens, whereas structures with a halogen bond between the water oxygen and C5‐X exist only for X = Br, I, and At. Structures with two waters forming a bridge between C4O and C5‐X (through hydrogen‐ and halogen‐bonding interactions) exist for all halogens except F. The absence of a halogen‐bonded structure in singly‐hydrated ClmU is therefore attributed to the competing hydrogen‐bonding interaction with C4O4. The halogen‐bond angle in the doubly‐hydrated structures (150–160°) is far from the expected linearity of halogen bonds, indicating that significantly non‐linear halogen bonds may exist in complex environments with competing interactions. © 2016 Wiley Periodicals, Inc.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Competition between hydrogen and halogen bonding in halogenated 1‐methyluracil: Water systems

Hogan

Mourik

2016

J Comput Chem

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“…The first, a halogen bond, which is formed when a positive region on the halogen in a molecule attracts a negative site (as in H 3 N•••F 2 , for example). The second, a σ‐hole, which is a region of deficiency of electron density on the electrostatic surface of the atom Y along the outer extension of the RY σ‐bond in molecules, which can be positive, negative, or neutral . The atom Y can be a halogen derivative X (X = Cl, Br, I), or any other main group element of the periodic table (mainly atoms of groups 14–17).…”

Section: Resultsmentioning

confidence: 99%

“…Thus, an atom possessing a positive σ‐hole in a molecule can attract the negative site on another molecule to form an intermolecular noncovalent interaction. Such an attractive interaction has been referred to as either halogen bonding, or σ‐hole centered bonding …”

Section: Resultsmentioning

confidence: 99%

Do surfaces of positive electrostatic potential on different halogen derivatives in molecules attract? like attracting like!

Varadwaj

Yamashita

2017

J Comput Chem

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Coulomb's law states that like charges repel, and unlike charges attract. However, it has recently been theoretically revealed that two similarly charged conducting spheres will almost always attract each other when both are in close proximity. Using multiscale first principles calculations, we illustrate practical examples of several intermolecular complexes that are formed by the consequences of attraction between positive atomic sites of similar or dissimilar electrostatic surface potential on interacting molecules. The results of the quantum theory of atoms in molecules and symmetry adapted perturbation theory support the attraction between the positive sites, characterizing the F•••X (X = F, Cl, Br) intermolecular interactions in a series of 20 binary complexes as closed-shell type, although the molecular electrostatic surface potential approach does not (a failure!). Dispersion that has an r dependence, where r is the equilibrium distance of separation, is found to be the sole driving force pushing the two positive sites to attract. © 2017 Wiley Periodicals, Inc.

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“…Despite these prior findings, the efficiency of the mPW1PW/6-31G * level was once more evaluated, within this new context, by comparison with the results obtained using a higher theory level that combines a long-range corrected hybrid functional, ωB97XD, with a much larger basis set, 6-311++G(2d,2p). The choice of this theory level was based on its well documented high performance regarding the description of hydrogen bonding [39][40][41][42].…”

Section: Computational Detailsmentioning

confidence: 99%

On the correction of calculated vibrational frequencies for the effects of the counterions — α,ω-diamine dihydrochlorides

et al. 2015

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The present work provides sets of correction factors to adjust the calculated vibrational frequencies of a series of α,ω-diamines hydrochloride salts to account for the intermolecular interactions with the counterion. The study was performed using different theory levels for predicting the vibrational data of isolated dicationic α,ω-diamines and their hydrochloride forms, with and without the explicit account of the interactions with the chloride counterions. Different sets of correction factors were determined for each theory level considering the four smallest elements for the α,ω-diamines series, while their transferability and reliability was evaluated considering the larger elements of the series. The theory level simplification was also evaluated and was found to neither compromise the vibrational frequencies estimates nor the magnitude and accuracy of the pre-defined scaling factors. This suggests that transferability of the correction factors is possible not only for different diamines but also between different levels of theory with the averaged group correction factor, ζ g (a) , being the best choice to account for the effects of the N-H · · · Cl interactions. The possibility of simplifying the theory level without compromising efficiency and accuracy is additionally of utmost importance. This computational approach can constitute a valuable tool in the future for studying the hydrochloride forms of larger and more complex diamine systems. Graphical Abstract A computational approach that may constitute a valuable tool for studying the hydrochloride forms of large and complex diamine systems. Correction factors to adjust the vibrational frequencies calculated for isolated dicationic primary diamines for the effects of the interactions with chloride counterions, without their explicit account in the calculations, are presented and evaluated for eficiency.

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Fluorines in tetrafluoromethane as halogen bond donors: Revisiting address the nature of the fluorine'sσ_hole

Cited by 49 publications

References 144 publications

Competition between hydrogen and halogen bonding in halogenated 1‐methyluracil: Water systems

Competition between hydrogen and halogen bonding in halogenated 1‐methyluracil: Water systems

Do surfaces of positive electrostatic potential on different halogen derivatives in molecules attract? like attracting like!

On the correction of calculated vibrational frequencies for the effects of the counterions — α,ω-diamine dihydrochlorides

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Fluorines in tetrafluoromethane as halogen bond donors: Revisiting address the nature of the fluorine'sσhole

Cited by 49 publications

References 144 publications

Competition between hydrogen and halogen bonding in halogenated 1‐methyluracil: Water systems

Competition between hydrogen and halogen bonding in halogenated 1‐methyluracil: Water systems

Do surfaces of positive electrostatic potential on different halogen derivatives in molecules attract? like attracting like!

On the correction of calculated vibrational frequencies for the effects of the counterions — α,ω-diamine dihydrochlorides

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Product

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Fluorines in tetrafluoromethane as halogen bond donors: Revisiting address the nature of the fluorine'sσ_hole