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Main Authors: Ma, Zhongjie, Jiang, Miao, Song, Yaohao, Sun, Aile, Yi, Shengzhu, Zhou, Chao, Huang, Xiang, Huang, Mingjun, Aya, Satoshi, Wei, Qi-Huo
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.00994
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author Ma, Zhongjie
Jiang, Miao
Song, Yaohao
Sun, Aile
Yi, Shengzhu
Zhou, Chao
Huang, Xiang
Huang, Mingjun
Aya, Satoshi
Wei, Qi-Huo
author_facet Ma, Zhongjie
Jiang, Miao
Song, Yaohao
Sun, Aile
Yi, Shengzhu
Zhou, Chao
Huang, Xiang
Huang, Mingjun
Aya, Satoshi
Wei, Qi-Huo
contents Ferroelectric nematic (NF) liquid crystals present a compelling platform for exploring topological defects in polar fields, while their structural properties can be significantly altered by ionic doping. In this study, we demonstrate that doping the ferroelectric nematic material RM734 with cationic polymers enable the formation of polymeric micelles that connect pairs of half-integer topological defects. Polarizing optical microscopy reveals that these string defects exhibit butterfly textures, featured with a two-dimensional polarization field divided by Néel-type kink-walls into domains exhibiting either uniform polarization or negative splay and bend deformations. Through analysis of electrophoretic motion and direct measurements of polarization divergences, we show that the string micelles are positively charged and their side regions exhibit positive bound charges. To elucidate these observations, we propose a charge double layer model for the string defects: the positive charged cationic polymer chains and densely packed RM734 molecules form a Stern charge layer, while small anionic ions and positive bound charges constitute the charge diffusion layer. Notably, our experiments indicate that only cationic polymer doping effectively induces the formation of these unique string defects. These findings enhance our understanding of ionic doping effects and provide valuable insights for engineering polar topologies in liquid crystal systems.
format Preprint
id arxiv_https___arxiv_org_abs_2406_00994
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Half-integer Topological Defects Paired via String Micelles in Polar Liquids
Ma, Zhongjie
Jiang, Miao
Song, Yaohao
Sun, Aile
Yi, Shengzhu
Zhou, Chao
Huang, Xiang
Huang, Mingjun
Aya, Satoshi
Wei, Qi-Huo
Soft Condensed Matter
Ferroelectric nematic (NF) liquid crystals present a compelling platform for exploring topological defects in polar fields, while their structural properties can be significantly altered by ionic doping. In this study, we demonstrate that doping the ferroelectric nematic material RM734 with cationic polymers enable the formation of polymeric micelles that connect pairs of half-integer topological defects. Polarizing optical microscopy reveals that these string defects exhibit butterfly textures, featured with a two-dimensional polarization field divided by Néel-type kink-walls into domains exhibiting either uniform polarization or negative splay and bend deformations. Through analysis of electrophoretic motion and direct measurements of polarization divergences, we show that the string micelles are positively charged and their side regions exhibit positive bound charges. To elucidate these observations, we propose a charge double layer model for the string defects: the positive charged cationic polymer chains and densely packed RM734 molecules form a Stern charge layer, while small anionic ions and positive bound charges constitute the charge diffusion layer. Notably, our experiments indicate that only cationic polymer doping effectively induces the formation of these unique string defects. These findings enhance our understanding of ionic doping effects and provide valuable insights for engineering polar topologies in liquid crystal systems.
title Half-integer Topological Defects Paired via String Micelles in Polar Liquids
topic Soft Condensed Matter
url https://arxiv.org/abs/2406.00994