具有增强机械性能的低电压响应型纳米复合材料--可改变形状的水凝胶/碳纳米纤维的制备与表征

IF 503.1 1区 医学 Q1 ONCOLOGY CA: A Cancer Journal for Clinicians Pub Date : 2024-11-14 DOI:10.1002/pol.20240746
Jiale Li, Qiang Ma, Guohe Xu, Chunqiang Jiang, Mengru Wang
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引用次数: 0

摘要

高电压响应性和较差的机械性能阻碍了电诱导形状变化水凝胶(EISCHs)的实际应用。在以前的工作中,人们只是通过提高交联度来改善机械性能,但这样做会降低变形能力。因此,我们在 EISCH 中引入了增强非变形水凝胶机械性能的纳米复合技术,从而成功合成了 Poly (N-isopropylacrylamide-co-5-acrylamido-1,10-phenanthroline bis (1. 10-phenanthroline) iron) 和 Poly (N-isopylacrylamide-co-5-acrylamido-1,10-phenanthroline bis (1. 10-phenanthroline) iron)、10-菲罗啉)铁(II))/亲水处理的羟基碳纳米纤维(P(NIPAM-Fe(phen)3)/HMWCNFs)纳米复合变形水凝胶。研究了不同亲水性羟基化碳纳米纤维(HMWCNFs)含量对水凝胶结构、溶胀、交联、力学和电致形变性能的影响。随着 HMWCNFs 含量的增加(0.2%-1.0%),拉伸强度和压缩强度也随之增加,分别是不含 HMWCNFs 水凝胶的 6.67 倍和 2.91 倍。在最低响应电压为 10 V 时,P(NIPAM-Fe(phen)3/HMWCNFs)水凝胶的变形能力高于不含 HMWCNFs 的水凝胶。HMWCNFs 与聚合物链之间的物理缠结和氢键作用降低了粘附能并提供了能量耗散。作为导电填料,HMWCNFs 促进了电子转移。在低压刺激下,5-丙烯酰胺基-1,10-菲罗啉双(1,10-菲罗啉)铁(II)(Fe(phen)3)网络铁(II)态和铁(III)态之间的转变导致水凝胶膨胀和收缩。
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Preparation and Characterization of Low-Voltage Responsive Nanocomposite Shape-Changing Hydrogels/Carbon Nanofibers With Enhanced Mechanical Properties
High-voltage responsiveness and poor mechanical properties hindered the practical applications of electro-induced shape-changing hydrogels (EISCHs). In previous work, mechanical properties were improved simply by increasing the degree of crosslinking, which resulted in reduced deformation capacity. Therefore, the nanocomposite technique of reinforcing nondeformable hydrogels' mechanical properties was introduced into EISCHs, resulting in the successful synthesis of Poly (N-isopropylacrylamide-co-5-acrylamido-1,10-phenanthroline bis (1,10-phenanthroline) iron (II))/hydrophilic-treated hydroxylated carbon nanofibers (P(NIPAM-Fe(phen)3)/HMWCNFs) nanocomposite shape-changing hydrogel that exhibits outstanding mechanical properties, doesn't have its deformation ability weakened and possesses low-voltage responsiveness in this work. The impact of various hydrophilic-treated hydroxylated carbon nanofibers (HMWCNFs) content on hydrogels' structure, swelling, crosslinking, mechanics and electro-induced shape-changing properties was investigated. As the HMWCNFs content increased (0.2%–1.0%), the tensile and compressive strengths increased, marking 6.67 times and 2.91 times rise over hydrogel without HMWCNFs. The deformation ability of P(NIPAM-Fe(phen)3/HMWCNFs) hydrogel was higher than without HMWCNFs at minimum response voltage 10 V. The physical entanglements and hydrogen bonding between HMWCNFs and polymer chains reduced adhesion energy and provided energy dissipation. HMWCNFs, as a conductive filler, facilitated electron transfer. The hydrogel swelled and shrank due to the transition between 5-acrylamido-1,10-phenanthroline bis (1,10-phenanthroline) iron (II) (Fe(phen)3) network iron (II) and iron (III) states under low-voltage stimulation.
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来源期刊
CiteScore
873.20
自引率
0.10%
发文量
51
审稿时长
1 months
期刊介绍: CA: A Cancer Journal for Clinicians" has been published by the American Cancer Society since 1950, making it one of the oldest peer-reviewed journals in oncology. It maintains the highest impact factor among all ISI-ranked journals. The journal effectively reaches a broad and diverse audience of health professionals, offering a unique platform to disseminate information on cancer prevention, early detection, various treatment modalities, palliative care, advocacy matters, quality-of-life topics, and more. As the premier journal of the American Cancer Society, it publishes mission-driven content that significantly influences patient care.
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