A quantum-chemical analysis on the Lewis acidity of diaryl-halonium ions

Robidas, Raphaël; Reinhard, Dominik; Huber, Stefan M.; Legault, Claude Y.

doi:10.26434/chemrxiv-2022-jtt63-v2

Cited by 3 publications

(2 citation statements)

References 21 publications

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“…29 Although the orbital composition does not account for the significant difference in Lewis acidity between cyclic and acyclic diarylhalonium compounds, the increased steric repulsion between the aryl ligands and approaching Lewis bases that is a result of a more obtuse C–X–C bond angle in acyclic compounds 16–18 may be an important factor. 34 Considering the design or selection of Lewis acid catalysts, one might anticipate that a stronger Lewis acid is more advantageous, and therefore the iodoniums would be favoured. However, there is at least one reported case in which a bromonium catalyst resulted in a higher yield of product than the corresponding iodonium catalyst highlighting the complexity of catalytic cycles.…”

Section: Resultsmentioning

confidence: 99%

Orbital analysis of bonding in diarylhalonium salts and relevance to periodic trends in structure and reactivity

et al. 2022

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Section: Resultsmentioning

confidence: 99%

Orbital analysis of bonding in diarylhalonium salts and relevance to periodic trends in structure and reactivity

et al. 2022

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“…Thus, iodonium salts featuring two holes at the iodine atom exhibit higher catalytic activity than - ----------------------------------------------cationic iodine(I)-based catalysts 28 and effectively catalyze a wide range of organic reactions. [29][30][31][32][33][34][35][36][37][38][39][40][41][42][43] Similarly, telluronium salts featuring three -holes at the tellurium atom represent a higher catalytic activity than that of tellurium(II) derivatives and lighter chalcogen(IV)-derived species. 44,45 Although onium salts were shown to catalyze a wide range of reactions, there is no single point of view on the nature of the electrophilic activation of reaction substrates by these species.…”

Section: Introductionmentioning

confidence: 99%

Solvent-modulated Binding Selectivity of Reaction Substrates to Onium-based Sigma-Hole Donors

Sysoeva

Novikov

Bolotin

2022

Preprint

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Combination of experimental data and results of DFT calculations indicates that the catalytic activity of chalconium and halonium salts served as sigma-hole donating organocatalysts cannot be clearly estimated via analysis of the electrostatic potential on the catalysts’ sigma-holes and values of the catalyst•••TS intermolecular interactions, such as polarization effects, charge transfer, or covalency of bonding. Moreover, the real catalytic effect might not correlate well with the values of Gibbs free energies of activation of the reactions, because solvation effects and other competitive binding processes play at least the same or even more important role in the catalysis. It was showed in present work, that the solvation either can lead to the increase of equilibrium concentration of reactive catalyst•••electrophile associates thus accelerating the reaction or brings favorable generation of catalyst•••nucleophile species resulting in suppression of the catalytic activity of the organocatalyst.

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Chiral Bromonium Salt (Hypervalent Bromine(III)) with N-Nitrosamine as a Halogen-Bonding Bifunctional Catalyst

Yoshida

Mino

et al. 2023

Molecules

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There has been a great focus on halogen-bonding as a unique interaction between electron-deficient halogen atoms with Lewis basic moieties. Although the application of halogen-bonded atoms in organic chemistry has been eagerly researched in these decades, the development of chiral molecules with halogen-bonding functionalities and their utilization in asymmetric catalysis are still in the\ir infancy. We have previously developed chiral halonium salts with amide functionalities, which behaved as excellent catalysts albeit in only two reactions due to the lack of substrate activation abilities. In this manuscript, we have developed chiral halonium salts with an N-nitrosamine moiety and applied them to the Mannich reaction of isatin-derived ketimines with malonic esters. The study focused on our novel bromonium salt catalyst which provided the corresponding products in high yields with up to 80% ee. DFT calculations of the chiral catalyst structure suggested that the high asymmetric induction abilities of this catalyst are due to the Lewis basic role of the N-nitrosamine part. To the best of our knowledge, this is the first catalytic application of N-nitrosamines.

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A quantum-chemical analysis on the Lewis acidity of diaryl-halonium ions

Cited by 3 publications

References 21 publications

Orbital analysis of bonding in diarylhalonium salts and relevance to periodic trends in structure and reactivity

Orbital analysis of bonding in diarylhalonium salts and relevance to periodic trends in structure and reactivity

Solvent-modulated Binding Selectivity of Reaction Substrates to Onium-based Sigma-Hole Donors

Chiral Bromonium Salt (Hypervalent Bromine(III)) with N-Nitrosamine as a Halogen-Bonding Bifunctional Catalyst

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