Intrinsically chiral ferronematic liquid crystals: An inversion of the helical twist sense at the chiral nematic – Chiral ferronematic phase transition

The ferroelectric nematic phase is a unique example of a polar phase without positional order of the constituent molecules. The properties of the ferronematic phase formed by intrinsically chiral molecules are discussed. Chirality makes the phase structure helical with the similar pitch length in th...

Full description

Saved in:
Bibliographic Details
Published in:Journal of molecular liquids 2022-09, Vol.361, p.119532, Article 119532
Main Authors: Pociecha, Damian, Walker, Rebecca, Cruickshank, Ewan, Szydlowska, Jadwiga, Rybak, Paulina, Makal, Anna, Matraszek, Joanna, Wolska, Joanna M., Storey, John M.D., Imrie, Corrie T., Gorecka, Ewa
Format: Article
Language:English
Subjects:
Chirality
Ferroelectric
Nematic
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The ferroelectric nematic phase is a unique example of a polar phase without positional order of the constituent molecules. The properties of the ferronematic phase formed by intrinsically chiral molecules are discussed. Chirality makes the phase structure helical with the similar pitch length in the N* and NF* phases, but with opposite sense. The materials show strong non-linear optical properties. [Display omitted] •Intrinsically chiral mesogens forming ferroelectric fluidic nematic, NF*, phase were obtained and studied.•In both, paraelectric and ferroelectric nematic phases, molecular chirality leads to helical structure.•Inversion of helix twist sense was observed at the N*-NF*phase transition.•Giant dielectric permittivity, above 104, was determined in ferroelectric nematic phase.•Strong nonlinear optical properties were confirmed for ferronematic phase. Strongly dipolar mesogenic compounds with a chiral center located in a lateral alkyl chain were synthesized, and shown to form the ferroelectric nematic phase. The presence of molecular chirality induced a helical structure in both the N* and NF* phases, but with opposite helix sense in the two phases. The relaxation frequency of the polar fluctuations is only weakly affected by helical structure, it was found to be slightly lower for the chiral NF* phase than for its achiral, non-branched counterpart with the same lateral chain length.
ISSN:0167-7322
1873-3166
DOI:10.1016/j.molliq.2022.119532