Theoretical and Crystallographic Study of Lead(IV) Tetrel Bonding Interactions

The ability of tetrahedral lead(IV) to establish noncovalent σ‐hole tetrel bonding interactions with electron‐rich atoms (ElRs; anions and Lewis bases) has been studied at the PBE0‐D3/def2‐TZVPD level of theory. An analysis of the Cambridge Crystallographic Database (CSD), which is a convenient stor...

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Published in:Chemistry : a European journal 2019-04, Vol.25 (23), p.6007-6013
Main Authors: Franconetti, Antonio, Frontera, Antonio
Format: Article
Language:English
Subjects:
Anions
Chemistry
Crystallography
density functional calculations
lead
noncovalent interactions
supramolecular chemistry
tetrel bonding
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description The ability of tetrahedral lead(IV) to establish noncovalent σ‐hole tetrel bonding interactions with electron‐rich atoms (ElRs; anions and Lewis bases) has been studied at the PBE0‐D3/def2‐TZVPD level of theory. An analysis of the Cambridge Crystallographic Database (CSD), which is a convenient storehouse of geometric information, has been performed to investigate the existence of tetrel bonding interactions involving tetrahedral lead(IV) derivatives. Several examples of tetrel bonding interactions that are crucial in crystal packing, ranging from 0D to 2D assemblies, have been found. In addition to the energetic and theoretical study of several XPb(CH3)3⋅⋅⋅ElR complexes (X=F, CN, CF3, and CH3), Bader's theory of atoms in molecules has also been used to further analyze and characterize the noncovalent interactions described herein. Making connections: The ability of organolead(IV) compounds and several electron‐rich molecules to establish noncovalent tetrel bonding interactions has been studied at the PBE0‐D3/def2‐TZVPD level of theory. Experimental evidence has been obtained from the Cambridge Structural Database of the existence of tetrel bonding interactions involving tetrahedral lead(IV) derivatives (see figure).
doi_str_mv 10.1002/chem.201900447
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subjects Anions
Chemistry
Crystallography
density functional calculations
lead
noncovalent interactions
supramolecular chemistry
tetrel bonding
title Theoretical and Crystallographic Study of Lead(IV) Tetrel Bonding Interactions
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