Structural Chemistry of Hypervalent Iodine Compounds

Justik, Michael W.

doi:10.1002/9780470682531.pat0939

Cited by 4 publications

(4 citation statements)

References 239 publications

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“…Structure of Iodonium Base Adducts. Solid-state (Xray) structures 15 of the adducts of the diphenyliodonium ion Ph 2 I + (1a) with chloride, 16 bromide, 16 iodide, 16 different pyridines, 9 18-crown-6, 8 and DABCO 17 have been reported in the literature. The Lewis adducts of 1a with benzoate and pnitrophenolates (4a and 4b), were prepared in this work by anion metathesis reactions (Scheme 2), 18 which were driven by the low solubility of potassium chloride in acetonitrile.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Lewis Acidity Scale of Diaryliodonium Ions toward Oxygen, Nitrogen, and Halogen Lewis Bases

et al. 2020

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Equilibrium constants for the associations of 17 diaryliodonium salts Ar2I+X– with 11 different Lewis bases (halide ions, carboxylates, p-nitrophenolate, amines, and tris(p-anisyl)phosphine) have been investigated by titrations followed by photometric or conductometric methods as well as by isothermal titration calorimetry (ITC) in acetonitrile at 20 °C. The resulting set of equilibrium constants K I covers 6 orders of magnitude and can be expressed by the linear free-energy relationship lg K I = s I LAI + LBI, which characterizes iodonium ions by the Lewis acidity parameter LAI, as well as the iodonium-specific affinities of Lewis bases by the Lewis basicity parameter LBI and the susceptibility s I. Least squares minimization with the definition LAI = 0 for Ph2I+ and s I = 1.00 for the benzoate ion provides Lewis acidities LAI for 17 iodonium ions and Lewis basicities LBI and s I for 10 Lewis bases. The lack of a general correlation between the Lewis basicities LBI (with respect to Ar2I+) and LB (with respect to Ar2CH+) indicates that different factors control the thermodynamics of Lewis adduct formation for iodonium ions and carbenium ions. Analysis of temperature-dependent equilibrium measurements as well as ITC experiments reveal a large entropic contribution to the observed Gibbs reaction energies for the Lewis adduct formations from iodonium ions and Lewis bases originating from solvation effects. The kinetics of the benzoate transfer from the bis(4-dimethylamino)-substituted benzhydryl benzoate Ar2CH–OBz to the phenyl(perfluorophenyl)iodonium ion was found to follow a first-order rate law. The first-order rate constant k obs was not affected by the concentration of Ph(C6F5)I+ indicating that the benzoate release from Ar2CH–OBz proceeds via an unassisted S N1-type mechanism followed by interception of the released benzoate ions by Ph(C6F5)I+ ions.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Lewis Acidity Scale of Diaryliodonium Ions toward Oxygen, Nitrogen, and Halogen Lewis Bases

et al. 2020

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“…In the past several decades, hypervalent iodine chemistry has witnessed prosperous development in organic synthesis. 1 On one hand, organic chemists are making use of the existing hypervalent iodine oxidants to discover new organic reactions. 2 On the other hand, many endeavors have been devoted to the development of novel hypervalent iodine oxidants, seeking new versatile applications in important synthetic transformations.…”

Section: Introductionsmentioning

confidence: 99%

A new hypervalent iodine(iii/v) oxidant and its application to the synthesis of 2H-azirines

et al. 2020

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“…Halogen bonding involving organoiodine compounds has been attributed to the presence of regions of positive electrostatic potential at the iodine center, known as σ holes, that can favorably interact with negatively charged atoms. − A number of reports have examined the theoretical basis for these I···E interactions, and Justik has recently discussed the history and connections between secondary bonding and halogen bonds, in the context of reviewing structural HVI chemistry . Kiprof has shown ab initio molecular orbital calculations focusing on iodine oxygen bonds in hypervalent 10-I-3 iodine compounds …”

Section: Introductionmentioning

confidence: 99%

“…27 recently discussed the history and connections between secondary bonding and halogen bonds, in the context of reviewing structural HVI chemistry. 33 Kiprof has shown ab initio molecular orbital calculations focusing on iodine oxygen bonds in hypervalent 10-I-3 iodine compounds. 34 The solubility and extended aggregation of HVI compounds can be modulated greatly by introduction of suitable intramolecular substituents to occupy coordination sites about the iodine center that might otherwise be involved in intermolecular interactions.…”

Section: ■ Introductionmentioning

confidence: 99%

Remote Substituents as Potential Control Elements for the Solid-State Structures of Hypervalent Iodine(III) Compounds

Rheingold

Protasiewicz

2021

Inorg. Chem.

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Hypervalent iodine (HVI) compounds are very important selective oxidants often employed in organic syntheses. Most HVI compounds are strongly associated in the solid state involving interactions between the electropositive iodine centers and nearby electron lone pairs of electronegative atoms. This study examines the impact of remote substituents on select families of HVI compounds as means to achieve predictable two-dimensional extended solid-state materials. Crystallographic analyses of 10 HVI compounds from several related classes of λ3 organoiodine(III) compounds, (diacetoxyiodo)benzenes, (dibenzoatoiodo)benzenes, [bis(trifluoroacetoxy)iodo]benzenes, and μ-oxo-[(carboxylateiodo)benzenes], provide insights into how remote substituents and the choice of carboxylate groups can impact intermolecular interactions in the solid state.

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Structural Chemistry of Hypervalent Iodine Compounds

Cited by 4 publications

References 239 publications

Lewis Acidity Scale of Diaryliodonium Ions toward Oxygen, Nitrogen, and Halogen Lewis Bases

Lewis Acidity Scale of Diaryliodonium Ions toward Oxygen, Nitrogen, and Halogen Lewis Bases

A new hypervalent iodine(iii/v) oxidant and its application to the synthesis of 2H-azirines

Remote Substituents as Potential Control Elements for the Solid-State Structures of Hypervalent Iodine(III) Compounds

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