Random Liquid Crystalline Copolymers Consisting of Prolate and Oblate Liquid Crystal Monomers

Xu, Yang; Dupont, Robert L.; Yao, Yuxing; Zhang, Meng; Fang, Jen-Chun; Wang, Xiaoguang

doi:10.1021/acs.macromol.1c00006

Cited by 13 publications

(26 citation statements)

References 95 publications

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“…The thermomechanical response of LCEs is directional when the liquid crystalline orientation is aligned. − Liquid crystallinity within LCEs is based on the organization of molecular units (e.g., mesogens) via intermolecular interactions between the typically aromatic units in the segment . Aligned LCEs exhibit large and directional stimuli-response, associated with disruption of this orientational order. , Numerous reports detail thermotropic actuation of LCEs. ,− …”

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confidence: 99%

Degree of Orientation in Liquid Crystalline Elastomers Defines the Magnitude and Rate of Actuation

et al. 2023

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The anisotropy of liquid crystalline elastomers (LCEs) is derived from the interaction-facilitated orientation of the molecular constituents. Here, we correlate the thermomechanical response of a series of LCEs subjected to mechanical alignment to measurements of the Hermans orientation parameter. The LCEs were systematically prepared with varying concentrations of liquid crystalline mesogens, which affects the relative degree of achievable order. These compositions were subject to varying degrees of mechanical alignment to prepare LCEs with orientations that span a wide range of orientation parameters. The stimuli-response of the LCEs indicates that the liquid crystalline content defines the temperature of actuation, whereas the orientation parameter of the LCE is intricately correlated to both the total actuation strain of the LCE as well as the rate of thermomechanical response.

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confidence: 99%

Degree of Orientation in Liquid Crystalline Elastomers Defines the Magnitude and Rate of Actuation

et al. 2023

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“…To address the abovementioned issue, it is of significance to explore a new method for modulating emission colors based on the well-defined LC structure as a slight change in packing structure may give rise to unpredictable color alteration. − Random copolymerization of mesogens of different kinds has been demonstrated to be a simple yet effective synthetic method that can be used to tailor the LC properties. − Although copolymerization of different color-coded fluorophores has achieved variable emissions, − it is still rather difficult to achieve in ordered LC systems. The immiscibility of these common fluorophores may induce certain nanoscale phase separation or packing structural uncertainty due to the large differences in molecular dimension, geometry, etc. , Thus, it is desirable to explore suitable mesogenic fluorophore pairs, which should not only exhibit substantially different emissions but also have similar molecular architectures to facilitate mutual interaction and homogeneous coassembly into defined LC structures.…”

Section: Introductionmentioning

confidence: 99%

Positional Isomerism-Mediated Copolymerization Realizing the Continuous Luminescence Color-Tuning of Liquid-Crystalline Polymers

Zhang

Hao

et al. 2022

Macromolecules

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Liquid crystals with color-tunable light emission are important for a variety of applications; however, achieving multicolor light-emitting liquid crystals whose emission colors can be fine-tuned remains challenging because the limited derivatization of mesogenic fluorophores disfavors the diversity of the emission. Here, we present a positional isomerism-mediated copolymerization strategy to obtain liquid-crystalline polymers with continuous luminescence color-tuning ability. The introduced α−/β-cyanostilbene positional isomers possess very similar molecular structures, thus reducing the risk of assembly heterogeneity and facilitating the formation of a homogeneous and consistent liquid crystal mesophase. Meanwhile, a significant electronic effect was caused for fluorophores with positional isomerization, allowing the efficient tuning of emission colors via copolymerization. Especially with a gradual change in the composition of the copolymers, the emission color shift behaved in a continuous manner from blue to green. These cyanostilbenebased liquid-crystalline polymers also showed reversible photochromic fluorescence switching ability. This approach highlights the value of positional isomers to prepare color-tunable solid-state light-emitting materials, allowing control and fine-tuning of the emission property while maintaining the ordered assembly ability.

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“…Liquid crystalline (LC) polymer features great properties of ordered nanostructure, [ 1,2 ] efficient response to external stimuli, [ 3–5 ] and excellent mechanical performance, [ 6 ] making it a competitive candidate in preparing functional nanomaterials. Compared with main‐chain liquid crystalline polymers (MCLCPs), side‐chain liquid crystalline polymers (SCLCPs) have significant advantages in terms of chemical structural designability and aggregational structural complexity, which is of great importance in not only fundamental understanding of molecular assembly [ 7–9 ] but also nanotechnology applications. [ 10–12 ] Normally, the self‐assembly structures of SCLCPs can be adjusted from molecular level by changing LC mesogen, [ 13,14 ] flexible spacer, [ 15,16 ] or intermolecular interactions.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Phase Behavior of (Semifluorinated Alkane)‐Based Side‐Chain Liquid Crystalline Copolymers

Cheng

et al. 2022

Macromol. Rapid Commun.

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Side-chain liquid crystalline polymer (SCLCP) usually contains a simple and flexible homopolymer as main chain, while its effect on the self-assembly behavior is often ignored. In this work, in order to increase the structural complexity and investigate the interaction between the main chain and mesogens, perfluorinated segments are introduced into the main chain using a photoinduced Step Transfer-Addition & Radical-Termination polymerization method, producing a novel series of SCLCPs containing 4-methoxyphenyl benzoate mesogens, soft hydrocarbon spacers, and a strictly alternating perfluoroalkyl and alkyl backbone. By adjusting the length of spacers or perfluoroalkyl segments, several mesophases with complex chain packing structures are achieved. This design strategy that constructing highly ordered liquid crystalline (LC) structures from SCLCPs with precise chemical structure provides a facile way toward novel LC nanomaterials.

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Random Liquid Crystalline Copolymers Consisting of Prolate and Oblate Liquid Crystal Monomers

Cited by 13 publications

References 95 publications

Degree of Orientation in Liquid Crystalline Elastomers Defines the Magnitude and Rate of Actuation

Degree of Orientation in Liquid Crystalline Elastomers Defines the Magnitude and Rate of Actuation

Positional Isomerism-Mediated Copolymerization Realizing the Continuous Luminescence Color-Tuning of Liquid-Crystalline Polymers

Synthesis and Phase Behavior of (Semifluorinated Alkane)‐Based Side‐Chain Liquid Crystalline Copolymers

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