Topology-Driven Mechanical Behavior of Liquid Crystal Elastomers via a Dynamic Mechanical Analyzer

IF 4.7 2区化学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

ACS Applied Polymer Materials Pub Date : 2025-09-05 DOI:10.1021/acsapm.5c02286

Yan-Ting Lin, , , Chung-Yu Kuo, , , Kai-Hung Chuang, , and , Chun-Yen Liu*,

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Abstract

Traditional vitrimers are cross-linked materials with plasticity that can be reprogrammed through transesterification reactions. To impart shape memory functionality to vitrimers, this study employed liquid crystal monomers and synthesized a series of reprogrammable shape-memory elastomers via Michael addition. To understand how a material deforms under sinusoidal stress and to measure the resulting strain, a dynamic mechanical analyzer (DMA) was employed to investigate the viscoelastic behavior of the synthesized materials. By analyzing their response to periodic stress, key mechanical properties were determined. DMA and thermal actuation tests revealed the phase transition characteristics of the elastomer. Stress relaxation experiments revealed that the synthesized liquid crystal elastomers (LCEs) exhibited significant stress relaxation behavior at 80 °C. Furthermore, when the LCEs were heated to 80 °C without applied stress, their molecular alignment decreased. The characteristic properties of the liquid crystal elastomers, as well as the thermal actuation behavior of the synthesized 5LCE film, were further confirmed via these analyses.

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基于动态力学分析仪的液晶弹性体拓扑驱动力学行为

传统的玻璃体是具有可塑性的交联材料，可以通过酯交换反应重新编程。为了赋予玻璃聚合体形状记忆功能，本研究采用液晶单体，并通过Michael加法合成了一系列可重新编程的形状记忆弹性体。为了了解材料在正弦应力下如何变形并测量产生的应变，采用动态力学分析仪（DMA）来研究合成材料的粘弹性行为。通过分析其周期性应力响应，确定了关键力学性能。DMA和热致动试验揭示了弹性体的相变特性。应力松弛实验表明，合成的液晶弹性体（LCEs）在80℃时表现出明显的应力松弛行为。此外，当lce在没有施加应力的情况下加热到80°C时，它们的分子排列降低。通过这些分析，进一步证实了液晶弹性体的特性，以及合成的5LCE薄膜的热致动行为。

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来源期刊

ACS Applied Polymer Materials Multiple-

CiteScore

7.20

自引率

6.00%

发文量

810

期刊介绍： ACS Applied Polymer Materials is an interdisciplinary journal publishing original research covering all aspects of engineering, chemistry, physics, and biology relevant to applications of polymers. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrates fundamental knowledge in the areas of materials, engineering, physics, bioscience, polymer science and chemistry into important polymer applications. The journal is specifically interested in work that addresses relationships among structure, processing, morphology, chemistry, properties, and function as well as work that provide insights into mechanisms critical to the performance of the polymer for applications.