Abstract

The intriguing twist-bend nematic (NTB) phase is formed, primarily, by liquid crystal dimers having odd spacers. Typically, the phase is preceded by a nematic (N) phase via a weak first-order transition. Our aim is to obtain dimers where the NTB phase is formed directly from the isotropic (I) phase via a strong first-order phase transition. The analogy between such behaviour and that of the smectic A (SmA)–N–I sequence suggests that this new dimer will require a short spacer. This expectation is consistent with the prediction of a molecular field theory, since the decrease in the spacer length results in an increase in the molecular curvature. A vector of odd dimers based on benzoyloxybenzylidene mesogenic groups with terminal ethoxy groups has been synthesised with spacers composed of odd numbers of methylene groups. Spacers having 5, 7, 9 and 11 methylene groups are found to possess the conventional phase sequence NTB–N–I; surprisingly, for the propane spacer, the NTB phase is formed directly from the I phase. The properties of these dimers have been studied with care to ensure that the identification of the NTB phase is reliable.

Highlights

  • In 1888 Reinitzer reported the synthesis of cholesteryl benzoate with its unusual double melting and striking colours seen on cooling the compound to just above the freezing point [1]

  • The texture observed on lowering the temperature to the twist-bend nematic phase is given in Fig, 2(b) and is a mixture of a polygonal together with a rope-like form

  • This is often observed for the NTB phase and is related to a periodic form resulting from the helicoidal structure with its short pitch [7, 20]

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Summary

Introduction

In 1888 Reinitzer reported the synthesis of cholesteryl benzoate with its unusual double melting and striking colours seen on cooling the compound to just above the freezing point [1]. Studies of other analogous odd liquid crystal dimers [13] and their mixtures [14] confirm this result; it is observed that as the nematic range increases so the strength of the NTB –N transition decreases [15] Such behaviour is analogous to that of compounds exhibiting both nematic and smectic A phases [16]; this is not surprising given the formal similarity between the NTB and smectic A phases [4,17]. This analogy would suggest that the twist-bend nematic phase might be formed directly from the isotropic phase via a first-order transition

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