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Research Progress in Biomimetic Actuators of Responsive Cross-linked Liquid Crystal Polymer
- Acta Polymerica Sinica Vol. 52, Issue 2, Pages: 124-145(2021)
- 作者机构:
郑州大学材料科学与工程学院 郑州 450001
- 作者简介:
- 基金信息:
DOI:10.11777/j.issn1000-3304.2020.20179
CLC:Published:3 February 2021,
Published Online:30 September 2020,
Received:30 July 2020,
Revised:24 August 2020,
扫 描 看 全 文
Ge-ge Wang, Ju-zhong Zhang, Shui-ren Liu, Xiang-hong Wang, Xu-ying Liu, Jin-zhou Chen. Research Progress in Biomimetic Actuators of Responsive Cross-linked Liquid Crystal Polymer. [J]. Acta Polymerica Sinica 52(2):124-145(2021)
Ge-ge Wang, Ju-zhong Zhang, Shui-ren Liu, Xiang-hong Wang, Xu-ying Liu, Jin-zhou Chen. Research Progress in Biomimetic Actuators of Responsive Cross-linked Liquid Crystal Polymer. [J]. Acta Polymerica Sinica 52(2):124-145(2021) DOI: 10.11777/j.issn1000-3304.2020.20179.
摘要
交联液晶高分子兼具液晶取向有序性和交联聚合物熵弹性等特点,能够以动态可调节和可逆的方式来模仿生物体的行为,在仿生器件、柔性机器人、智能表面、生物医药等领域具有良好的应用前景. 本综述总结了近几年智能响应性交联液晶高分子在仿生致动器方面的研究进展,从响应性交联液晶高分子的结构和驱动机理出发,讨论了响应性交联液晶高分子的合成工艺、制备技术和成型方法,以及响应性交联液晶高分子对光、热、磁、湿度的响应. 此外,介绍了响应性交联液晶高分子致动器在柔性机器人、人工肌肉、微流体运输等领域的应用. 最后,对响应性交联液晶高分子的发展前景进行了展望. 这项工作主要讨论了响应性交联液晶高分子,旨在为具有新颖功能和更有挑战性的智能微型致动器提供新的设计思路.
Abstract
Cross-linked liquid crystal polymer (CLCP)
as a combination of the order of liquid crystal orientation and the entropy elasticity of the polymer network
has exhibited unique properties such as actuation
soft elasticity
and birefringence. CLCP can mimic the behavior of organisms in a dynamically adjustable and reversible way to achieve actuation. When subjected to a specific external stimulus (such as light
heat
magnetism
or humidity)
CLCP responds to the stimuli by presenting changes in LC arrangement at the micro level and reversible shape or size changes at the macro level. Because of the initial arrangement of the mesogen memorized through the network
the macroscopic deformation of CLCP is reversible. Materials with photothermal conversion effect
such as graphene
carbon nanotubes
and gold nanorods
can be combined with polymers to convert the absorbed light energy into heat energy so as to realize photothermal actuation. In addition
when photo-response moieties like azobenzene are appropriately added to CLCP
the reversible
trans-cis
isomerization of azobenzene under specific wavelengths of light will cause the change of LC director
thus bringing out its photodeformation performance. Moreover
there is also magnetic stimulation driven by magnetic fields and humidity stimulation based on CLCP reversible anisotropic contraction or expansion. In this review
the synthesis methods of CLCP (one-step cross-linking
two-step cross-linking
post-crosslinking
and dynamic covalent bond cross-linking) and molding technology (inkjet printing
microfluidic transportation
soft lithography
direct laser writing
and 4D printing) are described. Through reasonable structure and material design
CLCP can be fabricated into a variety of flexible actuators. Herein
this review mainly summarizes the recent research progress in the applications of intelligently responsive cross-linked liquid crystal polymer in the field of the biomimetic actuators
such as artificial muscles
and microfluidic transportation. The future development and challenges of intelligently responsive cross-linked liquid crystal polymer in actuator field are also discussed.
关键词
液晶高分子合成方法成型技术刺激响应仿生致动器
Keywords
Liquid crystal polymerSynthesis methodMolding technologyStimulus responseBionic actuator
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