6533b82efe1ef96bd1293e68
RESEARCH PRODUCT
Helix Inversion Controlled by Molecular Motors in Multistate Liquid Crystals.
Dmitry MorozovFederico LanciaBen L. FeringaJiawen ChenNathalie KatsonisAlexander Ryabchunsubject
Materials scienceMOTIONchiralitynanotekniikka02 engineering and technologyAdvanced materials010402 general chemistrylight‐responsive materials01 natural sciencesmolecular motorslight-responsive materialsliquid crystalsLiquid crystalMolecular motorMolecular motionmolekyylimoottoritGeneral Materials ScienceSoft matterbusiness.industryMechanical EngineeringmolekyylitAMPLIFICATIONSWITCHESDRIVENkiteet021001 nanoscience & nanotechnology0104 chemical sciencesCHIRALITYMechanics of MaterialsChemical physicsHelixvalokemiaPhotonics0210 nano-technologyChirality (chemistry)businessREORGANIZATIONdescription
Unravelling the rules of molecular motion is a contemporary challenge that promises to support the development of responsive materials and is likely to enhance the understanding of functional motion. Advances in integrating light‐driven molecular motors in soft matter have led to the design and realization of chiral nematic (cholesteric) liquid crystals that can respond to light with modification of their helical pitch, and also with helix inversion. Under illumination, these chiral liquid crystals convert from one helical geometry to another. Here, a series of light‐driven molecular motors that feature a rich configurational landscape is presented, specifically which involves three stable chiral states. The succession of chiral structures involved in the motor cycle is transmitted at higher structural levels, as the cholesteric liquid crystals that are formed can interconvert between helices of opposite handedness, reversibly. In these materials, the dynamic features of the motors are thus expressed at the near‐macroscopic, functional level, into addressable colors that can be used in advanced materials for tunable optics and photonics. peerReviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-11-01 | Advanced materials (Deerfield Beach, Fla.) |