The Chalcogen Bond in Crystalline Solids: A World Parallel to Halogen Bond

Scilabra, Patrick; Terraneo, Giancarlo; Resnati, Giuseppe

doi:10.1021/acs.accounts.9b00037

Cited by 368 publications

(303 citation statements)

References 98 publications

(139 reference statements)

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“…Through these positive potentials, the molecule can interact attractively with negative sites, such as lone pairs, π-electrons, and anions [2][3][4][5]. This accounts for numerous noncovalent interactions that have been known for many years [3,4,[11][12][13][14][15][16][17][18], and provides important routes to self-assembly in crystal engineering [19,20].…”

Section: σ-Holes and π-Holesmentioning

confidence: 99%

An Overview of Strengths and Directionalities of Noncovalent Interactions: σ-Holes and π-Holes

2019

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Quantum mechanics, through the Hellmann–Feynman theorem and the Schrödinger equation, show that noncovalent interactions are classically Coulombic in nature, which includes polarization as well as electrostatics. In the great majority of these interactions, the positive electrostatic potentials result from regions of low electronic density. These regions are of two types, designated as σ-holes and π-holes. They differ in directionality; in general, σ-holes are along the extensions of covalent bonds to atoms (or occasionally between such extensions), while π-holes are perpendicular to planar portions of molecules. The magnitudes and locations of the most positive electrostatic potentials associated with σ-holes and π-holes are often approximate guides to the strengths and directions of interactions with negative sites but should be used cautiously for this purpose since polarization is not being taken into account. Since these maximum positive potentials may not be in the immediate proximities of atoms, interatomic close contacts are not always reliable indicators of noncovalent interactions. This is demonstrated for some heterocyclic rings and cyclic polyketones. We briefly mention some problems associated with using Periodic Table Groups to label interactions resulting from σ-holes and π-holes; for example, the labels do not distinguish between these two possibilities with differing directionalities.

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Section: σ-Holes and π-Holesmentioning

confidence: 99%

An Overview of Strengths and Directionalities of Noncovalent Interactions: σ-Holes and π-Holes

2019

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“…The hydrogen bond is undoubtedly the most important and prevalent noncovalent interaction . However, other elements belonging to groups 14 to 17 of the periodic table have a similar function . The electron density distribution in covalently bonded heavy atoms of groups 15 to 17 is anisotropic and frequently presents regions of positive (σ‐holes) and negative (σ‐lumps) electron density .…”

Section: Introductionmentioning

confidence: 99%

Anion Recognition by Neutral Chalcogen Bonding Receptors: Experimental and Theoretical Investigations

Navarro-García

Galmés

Velasco

et al. 2020

Chemistry A European J

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The utilization of neutral receptors for the molecular recognition of anions based on chalcogen bonding (ChB) is an undeveloped area of host‐guest chemistry. In this manuscript, the synthesis of two new families of sulfur, selenium, and tellurium‐based ChB binding motifs are reported. The stability of the thiophene, selenophene, and tellurophene binding motifs has enabled the determination of the association constants for ChB halide anion binding in the polar aprotic solvent THF by 1H, 77Se, and 125Te NMR experiments. Two different aromatic cores are used and one or two Ch‐binding motifs are incorporated with the purpose of encapsulating the anion, offering up to two concurrent chalcogen bonds. Theoretical calculations and NMR experiments reveal that, for S and Se receptors, hydrogen‐bonding interactions involving the acidic H atom adjacent to the chalcogen atom are energetically favored over the ChB interaction. However, for the tellurophene binding motif, the σ‐hole interaction is competitive and more favored than the hydrogen bond.

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“…Among the comprehensive topic of noncovalent interactions, the hydrogen bond (HB) is undoubtedly the most important and prevalent bonding . In HB the hydrogen atom is the electrophilic site, but other elements of the p‐block of the periodic table can behave as electrophile and give rise to attractive interactions with electron rich sites . The electron density distribution in covalently bonded atoms of p‐block is frequently anisotropic and presents regions of lower or higher electron density where the electrostatic potential is typically positive or negative, respectively .…”

Section: Introductionmentioning

confidence: 99%

“…The interest in ChB has increased exponentially in the last ten years . It has been recently used in catalysis, molecular recognition, and crystal engineering .…”

Section: Introductionmentioning

confidence: 99%

Charge‐Assisted Chalcogen Bonds: CSD and DFT Analyses and Biological Implication in Glucosidase Inhibitors

Galmés

Juan-Bals

Frontera

et al. 2020

Chemistry A European J

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This study reports a combined Cambridge Structural Database and theoretical DFT study of charge assisted chalcogen bonds involving sulfonium, selenonium, and telluronium cations. The chalcogen bond has been recently defined by IUPAC as the net attractive interaction between an electrophilic region associated with a chalcogen atom in a molecular entity and a nucleophilic region in another, or the same, molecular entity. Divalent chalcogen atoms typically have up to two σ‐holes and forms up to two ChBs; the same holds for tetravalent chalcogens which adopt a seesaw arrangement. In sulfonium, selenonium, and telluronium salts chalcogen atoms form three covalent bonds, three σ‐holes are located opposite to these bonds, and up to three charge assisted ChBs can be formed between these holes and the counterions. The covalent bond arrangement around these chalcogen atoms is similar to trivalent pnictogen atoms and translates into a similar pattern of noncovalent interactions. We have found and studied this type of charge‐assisted chalcogen bonds in various sulfonium ion‐containing inhibitors of glucosidase, for example, salacinol and kotalanol.

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The Chalcogen Bond in Crystalline Solids: A World Parallel to Halogen Bond

Cited by 368 publications

References 98 publications

An Overview of Strengths and Directionalities of Noncovalent Interactions: σ-Holes and π-Holes

An Overview of Strengths and Directionalities of Noncovalent Interactions: σ-Holes and π-Holes

Anion Recognition by Neutral Chalcogen Bonding Receptors: Experimental and Theoretical Investigations

Charge‐Assisted Chalcogen Bonds: CSD and DFT Analyses and Biological Implication in Glucosidase Inhibitors

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