# Confinement Reveals Hidden Splay-Bend Order in Twist-Bend Nematics

**Authors:** Szymon Drzazga, Piotr Kubala, Lech Longa

arXiv: 2508.21655 · 2026-03-13

## TL;DR

This study uses simulations to show how confinement in thin films reveals hidden splay-bend order in twist-bend nematic phases, leading to new phases and insights into molecular organization.

## Contribution

It demonstrates that confinement enhances and reveals splay-bend order, uncovering new nematic and smectic phases not observable in bulk materials.

## Key findings

- Confinement amplifies splay-bend order in twist-bend nematics.
- A smectic splay-bend phase emerges near confining surfaces.
- New phases appear during the transition from confined to bulk states.

## Abstract

Using extensive Monte Carlo (MC) and molecular dynamics (MD) simulations, we investigate how spatial confinement affects molecular organization within thin films of the nematic twist-bend ($\mathrm{N_{TB}}$) phase. Our simulations show that confinement markedly amplifies the otherwise elusive splay-bend order, primarily by suppressing the intrinsic three-dimensional heliconical structure characteristic of bulk $\mathrm{N_{TB}}$.   Remarkably, when the $\mathrm{N_{TB}}$ phase is confined between parallel walls imposing planar anchoring, and the bulk wave vector is oriented parallel to the walls, a smectic splay-bend ($\mathrm{S_{SB}}$) phase spontaneously emerges near the confining surfaces. This intermediate structure subsequently transforms into the bulk $\mathrm{N_{TB}}$ phase either directly via a smectic splay-bend-twist ($\mathrm{S_{SBT}}$) phase or through a sequence involving both the $\mathrm{S_{SBT}}$ and the nematic splay-bend-twist ($\mathrm{N_{SBT}}$) phases. Notably, the $\mathrm{N_{SBT}}$ phase becomes particularly pronounced as the molecular bend angle approaches its maximum attainable value in bulk $\mathrm{N_{TB}}$; this regime occurs in close proximity to the $\mathrm{N}\text{--}\mathrm{S_{A}}\text{--}\mathrm{S_{SB}}$ triple point on the bulk phase diagram.   Our findings reveal a compelling and intricate interplay among chirality, confinement, and molecular ordering, further evidenced by the calculated elementary director distortions. Crucially, this study opens promising avenues for experimental exploration: confined thin-film geometries serve as powerful model systems for revealing and characterizing novel nematic and smectic liquid-crystal phases that remain elusive in, or currently inaccessible to, bulk experiments.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/2508.21655/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/2508.21655/full.md

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Source: https://tomesphere.com/paper/2508.21655