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Short and Linear Intermolecular Tetrel Bonds to Tin. Cocrystal Engineering with Triphenyltin Chloride

Vijith Kumar, Carl Rodrigue, David L. Bryce

2020Crystal Growth & Design27 citationsDOI

Abstract

Group 14 (tetrel) elements potentially provide a region of low electronic density (σ-hole) and elevated electrostatic potential, which acts as an electrophilic site to form attractive interactions with electron-rich moieties. Tetrel bonds are the result of net attractive interaction between an electrophilic region associated with a tetrel atom in a molecular entity and a nucleophilic region in another, or the same, molecular entity. Here, we describe a systematic study of the potential utility of tetrel bonds to tin for engineering novel cocrystalline architectures. We report the preparation of 10 new tetrel-bonded cocrystals of triphenyltin chloride with various Lewis bases featuring oxygen and nitrogen electron donor atoms. Single-crystal X-ray diffraction studies reveal that the formation of short and directional Sn···O and Sn···N tetrel bonds along the extension of the Cl–Sn covalent bond is chiefly responsible for the self-assembly of the two complementary components. Normalized contact parameters of approximately 0.6, tetrel bond angles of approximately 170–180°, and lengthening of the covalent Sn–Cl bond by 6–9% upon cocrystallization are all characteristic of the observed tetrel bonds to tin. Substantial changes in the isotropic 119Sn chemical shifts suggest the persistence of the tin tetrel bond in solution.

Topics & Concepts

TinCovalent bondCrystallographyElectrophileChemistryCrystal engineeringCrystal structureSupramolecular chemistryOrganic chemistryCatalysisCrystallography and molecular interactionsOrganometallic Compounds Synthesis and CharacterizationCrystal structures of chemical compounds
Short and Linear Intermolecular Tetrel Bonds to Tin. Cocrystal Engineering with Triphenyltin Chloride | Litcius