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RESEARCH PRODUCT

Naturally occurring polyphenols as building blocks for supramolecular liquid crystals – substitution pattern dominates mesomorphism

Christoph WölperMichael GieseJan BalszuweitMarkus MezgerMarkus MezgerJens VoskuhlMarco SacconeMarco SacconeMeik BlankeConstantin G. Daniliuc

subject

ChemistryHydrogen bondLiquid crystallineProcess Chemistry and TechnologyChemieBiomedical EngineeringSupramolecular chemistryEnergy Engineering and Power Technology02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnology01 natural sciencesIndustrial and Manufacturing Engineering0104 chemical sciencesCrystallographyChemistry (miscellaneous)Liquid crystalSupramolecular Chemistry Liquid Crystals Crystal Engineering Hydrogen BondingMaterials ChemistryChemical Engineering (miscellaneous)Settore CHIM/07 - Fondamenti Chimici Delle Tecnologie0210 nano-technology

description

A modular supramolecular approach towards hydrogen-bonded liquid crystalline assemblies based on naturally occurring polyphenols is reported. The combination of experimental observations, crystallographic studies and semi-empirical analyses of the assemblies provides insight into the structure–property relationships of these materials. Here a direct correlation of the number of donor OH-groups as well as their orientation with the mesomorphic behavior is reported. We discovered that the number and orientation of the OH-groups have a stronger influence on the mesomorphic behavior of the supramolecular assemblies than the connectivity (e.g. stilbenoid or chalconoid) of the hydrogen bond donors. Furthermore, the photo-switching behavior of selected complexes containing azopyridine ligands was investigated. This study will help future scientists to gain a deeper understanding of the underlying mechanisms and structure–property relationships of supramolecular assemblies with mesomorphic behavior, which is still one of the major challenges in current science.

yearjournalcountryeditionlanguage
2021-05-01Molecular Systems Design & Engineering
https://doi.org/10.1039/d0me00171f