Issue 25, 2024

Polymerisation of twist-bend nematic textures for electro-optical applications

Abstract

Polymer-stabilised liquid crystals (PSLCs) have recently been used to maintain the focal conic domains (FCDs) typical of the smectic A phase in the nematic phase for smart window applications. The newly discovered twist-bend nematic phase of bent-shaped dimers also exhibits FCDs due to its pseudo-layered structure. The variety of topological defects in the NTB phase is arguably even greater than in the smectic A phase, but the NTB phase is often metastable and usually crystallises at room temperature, which hinders its use in electro-optical applications. Here we show how different textures (FCDs, rope-like texture, double helices) of the NTB phase can be polymerised and then maintained in the nematic phase, at room temperature. This allows us to combine in PSLCs the optical properties of these defects, the thermal stability of the nematic phase and its reversible response to an electric field. We also show that the polymerised FCDs of the NTB phase could be used in smart glass applications and that the polymerised rope-like texture could be of interest for optical modulators and beam steering. In addition, the polymerisation of double helices could help to better understand their formation and structure in the NTB phase. More fundamentally, our work shows that despite the lack of density modulation, the textures of the NTB phase, thanks to its periodic character, can be exploited in the same way as those of the smectic A phase.

Graphical abstract: Polymerisation of twist-bend nematic textures for electro-optical applications

Supplementary files

Article information

Article type
Paper
Submitted
29 Feb 2024
Accepted
29 Apr 2024
First published
07 May 2024

Soft Matter, 2024,20, 4859-4867

Polymerisation of twist-bend nematic textures for electro-optical applications

C. N. Mahyaoui, P. Davidson, C. Meyer and I. Dozov, Soft Matter, 2024, 20, 4859 DOI: 10.1039/D4SM00270A

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