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Cooperative effects between π-hole triel and π-hole chalcogen bonds.

Jingru ZhangWenzuo LiJianbo ChengZhenbo LiuQing-Zhong Li
Published in: RSC advances (2018)
MP2/aug-cc-pVTZ calculations have been performed on π-hole triel- and chalcogen-bonded complexes involving a heteroaromatic compound. These complexes are very stable with large interaction energy up to -47 kcal mol -1 . The sp 2 -hybridized nitrogen atom engages in a stronger π-hole bond than the sp-hybridized species although the former has smaller negative electrostatic potential. The sp 2 -hybridized oxygen atom in 1,4-benzoquinone is a weaker electron donor in the π-hole bond than the sp 2 -hybridized nitrogen atom. The π-hole triel bond is stronger than the π-hole chalcogen bond. A clear structural deformation is found for the triel or chalcogen donor molecule in these π-hole-bonded complexes. The triel bond exhibits partially covalent interaction, whereas the chalcogen bond exhibits covalent interaction in the SO 3 complexes of pyrazine and pyridine derivatives with a sp 2 -hybridized nitrogen atom. Intermolecular charge transfer (>0.2 e ) occurs to a considerable extent in these complexes. In ternary complexes involving an aromatic compound, wherein a triel bond and a chalcogen bond coexist, both the interactions are weakened or strengthened when the central aromatic molecule acts as a double Lewis base or plays a dual role of both a base and an acid. Both electrostatic and charge transfer effects have important contributions toward changes in the strength of both interactions.
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