Hierarchical Growth of Supramolecular Structures Driven by Pimerization of Tetrahedrally Arranged Bipyridinium Units

A shape‐persistent molecule, featuring four bipyridinium units, has been synthesized that upon reduction undergoes intermolecular pimerization because of the rigid architecture of the molecule. The pimerization process has been investigated by a variety of techniques, such as absorption measurements...

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Bibliographic Details
Published in:Chemistry : a European journal 2017-05, Vol.23 (26), p.6380-6390
Main Authors: Marchini, Marianna, Baroncini, Massimo, Bergamini, Giacomo, Ceroni, Paola, D'Angelantonio, Mila, Franchi, Paola, Lucarini, Marco, Negri, Fabrizia, Szreder, Tomasz, Venturi, Margherita
Format: Article
Language:English
Subjects:
Chemical synthesis
Chemistry
Computer applications
Diamonds
electrochemistry
EPR spectroscopy
photochemistry
Pulse radiolysis
radiolytic reduction
Spectroscopy
Structural hierarchy
viologen
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Summary:A shape‐persistent molecule, featuring four bipyridinium units, has been synthesized that upon reduction undergoes intermolecular pimerization because of the rigid architecture of the molecule. The pimerization process has been investigated by a variety of techniques, such as absorption measurements, EPR spectroscopy, as well as gamma and pulse radiolysis, and compared with the behavior of a model compound. Computational studies have also been performed to support the experimental data. The most interesting feature of the tetramer is that pimerization occurs only above a threshold concentration of monoreduced species, on the contrary to the model compound. Furthermore, there is an increase of the apparent pimerization constant by increasing the concentration of reduced bipyridinium units. These results have been interpreted by the fact that pimerization is favored in the tetrahedrally shaped molecule because of a cooperative mechanism. Each multiply reduced molecule can indeed undergo multiple intermolecular interactions that enhance the stabilization of the system, also leading to hierarchical supramolecular growth. The resulting supramolecular system formed by such intermolecular pimerization should exhibit a diamond‐like structure, as suggested by a simplified modeling approach. The intermolecular nature of the pimerization process occurring in the tetramer has been demonstrated by measuring the corresponding bimolecular rate constant by pulsed radiolysis experiments. Stay in shape: A shape‐persistent molecule made of four tetrahedrally arranged bipyridinium units undergoes intermolecular pimerization upon reduction, leading to hierarchical supramolecular growth (see figure).
ISSN:0947-6539
1521-3765
DOI:10.1002/chem.201700137