Chiral carbonyl hypoiodites

Mattila, Milla; Rissanen, Kari; Ward, Jas S.

doi:10.1039/d3cc00259d

Cited by 9 publications

(23 citation statements)

References 38 publications

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“…15 Importantly, the N−Br and N−I bond lengths of substituted analogues vary insignificantly and are independent of the bond strength. 82 This observation is also in line with the strength independence of the N−I bond lengths of [bis(pyridine)iodine(I)] + complexes, 62 56 The influence of substituents on the stability and the geometry of halogen(I) complexes has been extensively studied using solution NMR, X-ray diffraction, and computations. 45,62,63,80 In short, electron-donating substituents strengthen while electron-withdrawing ones weaken the 3c4e halogen bond.…”

Section: ■ Fundamentalsmentioning

confidence: 58%

“…15,52 This protocol is typically performed in CH 2 Cl 2 but also works using other aprotic solvents, such as CH 3 CN. 53 Being a robust procedure, it can be applied for the preparation of halogen(I) complexes using various Lewis bases to yield virtually any type of [D 55,56 analogues. Importantly, this procedure is unlikely to provide pure product in the presence of protic solvents, such as alcohols or water, which have been used in some initial protocols.…”

Section: ■ Terminologymentioning

confidence: 99%

“…62,63 The (relative) stabilities of complexes formed upon the interaction of a halogenated Lewis base with a Journal of the American Chemical Society 6c. This reaction is most relevant for the estimation of the energies of the asymmetric halogen-bond complexes of, for instance, Nhalosaccharins, 50 N-halosuccinimides, 112 and hypoiodates 55,56 as well as of fluorine-centered halogen-bond complexes. 19 The energy cost of stretching a D−X covalent to a D ■ APPLICATIONS Halogen Transfer Reactions.…”

Section: Stability the Stability Of [D•••x•••dmentioning

confidence: 99%

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Halogen Bonds of Halogen(I) Ions─Where Are We and Where to Go?

Wieske,

Erdelyi

2023

J. Am. Chem. Soc.

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Halenium ions, X + , are particularly strong halogen-bond donors that interact with two Lewis bases simultaneously to form linear [D•••X•••D] + -type halonium complexes. Their three-center, four-electron halogen bond is both fundamentally interesting and technologically valuable as it tames the reactivity of halogen(I) ions, opening up new horizons in a variety of fields including synthetic organic and supramolecular chemistry. Understanding this bonding situation enables the development of improved halogen(I) transfer reactions and of advanced functional materials. Following a decade of investigations of basic principles, the range of applications is now rapidly widening. In this Perspective, we assess the status of the field and identify its key advances and the main bottlenecks. Clearing common misunderstandings that may hinder future progress, we aim to inspire and direct future research efforts.

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Section: ■ Fundamentalsmentioning

confidence: 58%

Section: ■ Terminologymentioning

confidence: 99%

Section: Stability the Stability Of [D•••x•••dmentioning

confidence: 99%

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Halogen Bonds of Halogen(I) Ions─Where Are We and Where to Go?

Wieske,

Erdelyi

2023

J. Am. Chem. Soc.

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“…The stability of halogen(I) complexes follows the trend: I > Br ≫ Cl, , which is reflected in the number of solid-state examples reported for each type, with Barluenga’s reagent, bis (pyridine)iodine(I) tetrafluoroborate, being the paradigm of iodine(I) complexes due to its widespread use in a multitude of organic transformations as a mild iodinating and oxidizing reagent. − Halogen(I) complexes, [L–X–L] + , feature a 3-center 4-electron ( 3c–4e ) bond, the symmetric nature of which has been confirmed computationally and in solution. , The negatively charged [O–I–O] − complexes are also known to have applications as organic reagents, and recently the ability to instigate asymmetry in the halogen bonding, via hydrogen bonding with one of the two saccharinato ligands, in the analogous [N–I–N] − complexes has been demonstrated . Interest in halogen(I) chemistry has been steadily increasing in recent years, with a whole slew of recent advances being reported, including the first examples of unrestrained heteroleptic, − hierarchical, and nucleophilic interactions of iodine(I) complexes, − as well as the resurgence of (isolable) non-chiral ,− and chiral carbonyl hypoiodites in the context of being halogen-bonded iodine(I) complexes.…”

Section: Introductionmentioning

confidence: 99%

Iodine(I) and Silver(I) Complexes Incorporating 3-Substituted Pyridines

Ward

2023

ACS Omega

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Building upon the first report of a 3-acetaminopyridine-based iodine(I) complex (1b) and its unexpected reactivity toward tBuOMe, several new 3-substituted iodine(I) complexes (2b–5b) have been synthesized. The iodine(I) complexes were synthesized from their analogous silver(I) complexes (2a–5a) via a silver(I) to iodine(I) cation exchange reaction, incorporating functionally related substituents as 3-acetaminopyridine in 1b; 3-acetylpyridine (3-Acpy; 2), 3-aminopyridine (3-NH2py; 3), and 3-dimethylaminopyridine (3-NMe2py; 4), as well as the strongly electron-withdrawing 3-cyanopyridine (3-CNpy; 5), to probe the possible limitations of iodine(I) complex formation. The individual properties of these rare examples of iodine(I) complexes incorporating 3-substituted pyridines are also compared to each other and contrasted to their 4-substituted counterparts which are more prevalent in the literature. While the reactivity of 1b toward etheric solvents could not be reproduced in any of the functionally related analogues synthesized herein, the reactivity of 1b was further expanded to a second etheric solvent. Reaction of bis(3-acetaminopyridine)iodine(I) (1b) and iPr2O gave [3-acetamido-1-(3-iodo-2-methylpentan-2-yl)pyridin-1-ium]PF6 (1d), which demonstrated potentially useful C–C and C–I bond formation under ambient conditions.

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“…Over the last decade, the + IÀ N XBs in [NÀ IÀ N] + has received much attention [36] and they are now being utilized for constructing capsules, [37,38] helicates [39] and metal-organic frameworks (MOFs) [40] unrestrained homoleptic [41,42] and heteroleptic [43][44][45] and hierarchical, [46] and nucleophilic interactions of iodine(I) complexes, [47][48][49] as well as stable nonchiral [50][51][52] and chiral carbonyl hypoiodites. [53] Compared to the much more explored CÀ I•••N XB systems, [44] oxygen atom as an XB acceptor has not attracted so much intention due to its lower nucleophilicity and inherent polydentate nature and electron ''push-pull'' property (Figure 2). However, the significance of X•••O(carbonyl/ether) interactions has been demonstrated in protein-drug complexes [54,55] and crystal engineering.…”

Section: Introductionmentioning

confidence: 99%

N−X⋅⋅⋅O−N Halogen Bonds in Complexes of N‐Haloimides and Pyridine‐N‐oxides: A Large Data Set Study

Puttreddy

Rautiainen

2023

Angewandte Chemie

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N−X⋅⋅⋅−O−N+ halogen‐bonded systems formed by 27 pyridine N‐oxides (PyNOs) as halogen‐bond (XB) acceptors and two N‐halosuccinimides, two N‐halophthalimides, and two N‐halosaccharins as XB donors are studied in silico, in solution, and in the solid state. This large set of data (132 DFT optimized structures, 75 crystal structures, and 168 1H NMR titrations) provides a unique view to structural and bonding properties. In the computational part, a simple electrostatic model (SiElMo) for predicting XB energies using only the properties of halogen donors and oxygen acceptors is developed. The SiElMo energies are in perfect accord with energies calculated from XB complexes optimized with two high‐level DFT approaches. Data from in silico bond energies and single‐crystal X‐ray structures correlate; however, data from solution do not. The polydentate bonding characteristic of the PyNOs’ oxygen atom in solution, as revealed by solid‐state structures, is attributed to the lack of correlation between DFT/solid‐state and solution data. XB strength is only slightly affected by the PyNO oxygen properties [(atomic charge (Q), ionization energy (Is,min) and local negative minima (Vs,min)], as the σ‐hole (Vs,max) of the donor halogen is the key determinant leading to the sequence N‐halosaccharin>N‐halosuccinimide>N‐halophthalimide on the XB strength.

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Chiral carbonyl hypoiodites

Abstract: Three chiral carbonyl hypoiodites, R-C(O)OI, have been prepared from N-protected (S)-valine to give the ligand-stabilised (S)-valinoyl hypoiodite complexes with 4-dimethylaminopyridine, 4-pyrrolidinopyridine, and 4-morpholinopyridine as the stabilising ligands. The identity of...

Cited by 9 publications

References 38 publications

Halogen Bonds of Halogen(I) Ions─Where Are We and Where to Go?

Halogen Bonds of Halogen(I) Ions─Where Are We and Where to Go?

Iodine(I) and Silver(I) Complexes Incorporating 3-Substituted Pyridines

N−X⋅⋅⋅O−N Halogen Bonds in Complexes of N‐Haloimides and Pyridine‐N‐oxides: A Large Data Set Study

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