Abstract
A library of dendronized cyclotriveratrylene (CTV) crowns substituted with chiral, racemic, or achiral peripheral alkyl chains, including enantiopure R and S branched alkyls, "racemic by mixture", "racemic by synthesis", n-octyl, and n-dodecyl groups was synthesized. In solvophobic solvents and in bulk they self-assemble in helical columns. Their solution and bulk shape-persistent supramolecular structures were determined by a complementary combination of circular dichroism (CD) and UV in solution and thin film, microspot CD in thin film, differential scanning calorimetry combined with fiber X-ray diffraction, computer simulation, and molecular models. In solution, self-assembly via a cooperative mechanism generates single-handed columns from enantiopure CTVs and mixtures of right- and left-handed columns from racemic by mixture, racemic by synthesis, other combinations of R and S, and even from achiral compounds. In bulk state all supramolecular columns form a 3D hexagonal crystalline phase, Φ(h)(k) (P6₃ symmetry), that can be obtained only from single-handed columns and a columnar hexagonal 2D liquid crystal, Φ(h). The highest order Φ(h)(k) consists of enantiopure single-handed columns that are slightly distorted 12-fold triple helices. The "hat-shaped" dendronized CTV assembles in bent-branch pine-tree columns that allow interdigitation of alkyl groups in adjacent columns regardless of their direction. Enantiomerically rich, racemic, and achiral compositions undergo deracemization in the crystal state by transfer of the transient disc-like conformer of dendronized CTV from column to column during crown inversion. Solid state NMR experiments identified motional processes that allow such transfer. This unprecedented supramolecular chiral self-sorting will impact the creation of functions in complex systems.
Highlights
Most natural compounds and biomacromolecules are homochiral
The structures of all assemblies generated from these dendronized CTV that are shape persistent in solution and in bulk were determined by a combination of complementary techniques including circular dichroism (CD)-UV in solution and thin film, microspot CD in thin film, differential scanning calorimetry (DSC), fiber XRD, and computer simulation of molecular models of the oriented fiber XRD to reveal the mechanisms of self-assembly, racemization, and deracemization during their helical supramolecular polymerization in solvophobic solvents and in their 3D Φhk and 2D Φh phases
Supramolecular columns self-assemble in solution through a cooperative nucleation−elongation mechanism with enthalpies ranging from 29 kcal/mol for enantiopure and racemic by mixture dendronized CTV to 18 kcal/mol for racemic by synthesis CTV
Summary
The generation and mechanisms of action of molecular and supramolecular chirality in the creation of supramolecular chiral assemblies are more recent and complex topics of research.[7−9] Creation of supramolecular chirality involves mechanisms of transfer and amplification of structural information mediated by a helical arrangement of building blocks The complexity of these mechanisms has only begun to be elucidated.[8] Crystallization of supramolecular homochiral and racemic systems as well as their deracemization entails the development of methodologies that are available for molecular but not supramolecular systems.[6] Knowledge from these developments will impact many areas of supramolecular chemistry and materials including organic electronics,[10] biological mimics, and many others. The models required to study various classes of self-assembling building
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