The Power of Fiber Twist

IF 16.4 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Accounts of Chemical Research Pub Date : 2021-05-13 DOI:10.1021/acs.accounts.1c00112

Xiang Zhou, Shaoli Fang, Xueqi Leng, Zunfeng Liu*, Ray H. Baughman*

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引用次数: 40

Abstract

Nature’s evolution over billions of years has led to the development of different kinds of twisted structures in a variety of biological species. Twisted fibers from nanoscale- to micrometer-scale diameter have been prepared by mimicking natural twisted structures. Mechanically inserting twist in a yarn is an efficient and important method, which generates internal stress, changes the macromolecular orientation, and increases compactness. Recently, twist insertion has been found to produce interesting fiber properties, including chemical, mechanical, electrical, and thermal properties. This Account summarizes recent progress in how twist insertion affects the chemical and physical properties of fibers and describes their applications in artificial spider silk, artificial muscles, refrigeration, and electricity generation.

Twist and associated chirality widely arise in nature from molecules to nano- and microscale materials to macroscopic objects such as DNA, RNA, peptides, and chromosomes. Such twisted architectures play an important role in improving the mechanical properties and enabling biological functions. Inspired by the beauty and interesting properties of twisted structures, a wide range of artificial chiral materials with twisted or coiled structures have been prepared, from organic and inorganic nanorods, nanotubes, and nanobelts to macroscopic architectures and buildings.

An efficient way to prepare twisted materials is by inserting twist in fibers or yarns, which is an ancient technique used to make yarns or ropes (Wang, R., et al. Science2019, 366, 216–221. Mu, J., et al. Science2019, 365, 150–155). During the twisting process, torque is generated in fibers or yarns, the structure of the polymer chains becomes helically oriented, and the fibers in a yarn become more compact. Therefore, the twisting of fibers and yarns can produce novel chemical, mechanical, electrical, and thermal properties (Dou, Y., et al. Nat. Commun.2019, 10, 1–10. Kim, S. H., et al. Science2017, 357, 773–778). This Account focuses on the novel properties generated by twist insertion. The mechanical stress and strain can be optimized in a yarn by twist insertion, and different types of fibers exhibit rather different mechanisms.

In the first section, we will focus on recent progress in improving the mechanical properties of twisted fibers, including carbon nanotube yarns, single-filament fibers, and hydrogel fibers. Torque was generated by twist insertion in a fiber or a yarn, and the balance of internal torsional stress can be changed by causing a change in yarn volume. This will result in twist release and torsional and tensile actuations of the yarn, which will be described in the second section. Twisting a yarn generally makes it more compact, which will result in a mechanically induced change in capacitance, supercapacitance, and other useful electrochemical properties when a conducting yarn is in an electrolyte. Such processes were used to develop novel devices for twist-based electricity generation, called twistrons, which will be discussed in the third section. Twist insertion or release also changes the polymer chain orientation or crystal structure, resulting in changes in entropy. This is called the twistocaloric effect, which was used to develop a new cooling method, and will be discussed in the last section.

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纤维捻度的力量

自然界数十亿年的进化导致了各种生物物种中不同种类的扭曲结构的发展。通过模拟自然扭曲结构，制备了从纳米级到微米级的扭曲纤维。机械加捻是纱线产生内应力、改变大分子取向、提高密实度的一种有效而重要的方法。最近，人们发现插入捻度可以产生有趣的纤维性能，包括化学、机械、电气和热性能。本文总结了捻度插入如何影响纤维的化学和物理性质的最新进展，并描述了它们在人造蜘蛛丝、人造肌肉、制冷和发电方面的应用。扭曲和相关手性广泛存在于自然界中，从分子到纳米和微观尺度的材料，再到宏观物体，如DNA、RNA、肽和染色体。这种扭曲结构在改善机械性能和实现生物功能方面发挥着重要作用。受扭曲结构的美丽和有趣性质的启发，从有机和无机纳米棒、纳米管、纳米带到宏观建筑和建筑物，各种具有扭曲或卷曲结构的人工手性材料已经被制备出来。一种有效的方法是在纤维或纱线中插入捻度，这是一种古老的技术，用于制造纱线或绳索(Wang, R.， et al.)。科学，2019,36(6):216-221。Mu, J，等。科学，2019,365,150-155)。在加捻过程中，纤维或纱线中产生扭矩，聚合物链的结构变成螺旋状，纱线中的纤维变得更加紧密。因此，纤维和纱线的加捻可以产生新的化学、机械、电气和热性能(Dou, Y.等)。中国生物医学工程学报，2019,31(1):391 - 391。金，S. H.等。科学学报，2017,35(7):773-778。本帐户的重点是由捻插入产生的新特性。通过加捻可以优化纱线的机械应力和应变，不同类型的纤维表现出不同的机理。在第一部分中，我们将重点介绍在改善扭曲纤维的力学性能方面的最新进展，包括碳纳米管纤维、单长丝纤维和水凝胶纤维。扭力是通过在纤维或纱线中插入捻度而产生的，通过引起纱线体积的变化可以改变内扭应力的平衡。这将导致捻度释放和纱线的扭转和拉伸驱动，这将在第二节中描述。捻捻纱线通常会使其更加致密，当导电纱线处于电解质中时，这将导致机械诱导的电容、超级电容和其他有用的电化学性能的变化。这样的过程被用来开发新的设备，以扭转为基础的发电，称为twistrons，这将在第三节讨论。扭的插入或释放也会改变聚合物链的取向或晶体结构，从而导致熵的变化。这就是所谓的扭转热效应，它被用来开发一种新的冷却方法，并将在最后一节讨论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Accounts of Chemical Research 化学-化学综合

CiteScore

31.40

自引率

1.10%

发文量

312

审稿时长

2 months

期刊介绍： Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.