A. Carlsson scite author profile

Halogen bonding is a recently rediscovered secondary interaction that shows potential to become a complementary molecular tool to hydrogen bonding in rational drug design and in material sciences. Whereas hydrogen bond symmetry has been the subject of systematic studies for decades, the understanding of the analogous three-center halogen bonds is yet in its infancy. The isotopic perturbation of equilibrium (IPE) technique with (13)C NMR detection was applied to regioselectively deuterated pyridine complexes to investigate the symmetry of [N-I-N](+) and [N-Br-N](+) halogen bonding in solution. Preference for a symmetric arrangement was observed for both a freely adjustable and for a conformationally restricted [N-X-N](+) model system, as also confirmed by computation on the DFT level. A closely attached counterion is shown to be compatible with the preferred symmetric arrangement. The experimental observations and computational predictions reveal a high energetic gain upon formation of symmetric, three-center four-electron halogen bonding. Whereas hydrogen bonds are generally asymmetric in solution and symmetric in the crystalline state, the analogous bromine and iodine centered halogen bonds prefer symmetric arrangement in solution.

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Substituent Effects on the [N–I–N]⁺ Halogen Bond

Carlsson

et al. 2016

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We have investigated the influence of electron density on the three-center [N–I–N]+ halogen bond. A series of [bis(pyridine)iodine]+ and [1,2-bis((pyridine-2-ylethynyl)benzene)iodine]+ BF4– complexes substituted with electron withdrawing and donating functionalities in the para-position of their pyridine nitrogen were synthesized and studied by spectroscopic and computational methods. The systematic change of electron density of the pyridine nitrogens upon alteration of the para-substituent (NO2, CF3, H, F, Me, OMe, NMe2) was confirmed by 15N NMR and by computation of the natural atomic population and the π electron population of the nitrogen atoms. Formation of the [N–I–N]+ halogen bond resulted in >100 ppm 15N NMR coordination shifts. Substituent effects on the 15N NMR chemical shift are governed by the π population rather than the total electron population at the nitrogens. Isotopic perturbation of equilibrium NMR studies along with computation on the DFT level indicate that all studied systems possess static, symmetric [N–I–N]+ halogen bonds, independent of their electron density. This was further confirmed by single crystal X-ray diffraction data of 4-substituted [bis(pyridine)iodine]+ complexes. An increased electron density of the halogen bond acceptor stabilizes the [N···I···N]+ bond, whereas electron deficiency reduces the stability of the complexes, as demonstrated by UV-kinetics and computation. In contrast, the N–I bond length is virtually unaffected by changes of the electron density. The understanding of electronic effects on the [N–X–N]+ halogen bond is expected to provide a useful handle for the modulation of the reactivity of [bis(pyridine)halogen]+-type synthetic reagents.

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Counterion influence on the N–I–N halogen bond

et al. 2015

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The nature of [N–Cl–N]⁺and [N–F–N]⁺halogen bonds in solution

et al. 2014

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Symmetry of [N–X–N]⁺halogen bonds in solution

et al. 2012

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A. Carlsson

Symmetric Halogen Bonding Is Preferred in Solution

Substituent Effects on the [N–I–N]⁺ Halogen Bond

Counterion influence on the N–I–N halogen bond

The nature of [N–Cl–N]⁺and [N–F–N]⁺halogen bonds in solution

Symmetry of [N–X–N]⁺halogen bonds in solution

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A. Carlsson

Symmetric Halogen Bonding Is Preferred in Solution

Substituent Effects on the [N–I–N]+ Halogen Bond

Counterion influence on the N–I–N halogen bond

The nature of [N–Cl–N]+and [N–F–N]+halogen bonds in solution

Symmetry of [N–X–N]+halogen bonds in solution

Contact Info

Product

Resources

About

Substituent Effects on the [N–I–N]⁺ Halogen Bond

The nature of [N–Cl–N]⁺and [N–F–N]⁺halogen bonds in solution

Symmetry of [N–X–N]⁺halogen bonds in solution