Cellulose nanocomposite tough hydrogels: synergistic self-healing, adhesive and strain-sensitive properties

IF 2.9 4区化学 Q2 POLYMER SCIENCE Polymer International Pub Date : 2024-04-25 DOI:10.1002/pi.6644

Mohammed Nujud Badawi, Namrata Agrawal, Yogesh Kumar, Mujeeb Khan, Mohammad Rafe Hatshan, Abdulmajeed Abdullah Alayyaf, Syed Farooq Adil

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Abstract

Recent advancements are notable in electrically conductive hydrogels emulating human skin functions. However, a significant challenge remains: crafting a single conductive gel that integrates self-healing, robust mechanical strength, and excellent electrical traits. Our innovation lies in a strong, lightweight, curable gel achieved through multiple coordination bonds between cellulose crystals and acid-treated multi-walled carbon nanotubes (MWCNTs) in a polymer network. Embedded MWCNTs act as dynamic bridges within a porous structure, giving exceptional mechanical performance. Reversible coordination interactions confer remarkable recovery and reliable mechanical and electrical self-healing. Additionally, these ionic gels function as adaptable stress sensors, detecting significant movements like finger and joint motions. This work introduces MWCNT-incorporated nanomaterials with good stretchability, high ion conductivity, remarkable self-healing nature, and good stress sensitivity. Such proteins hold promise for electronic sensors, wearable devices, and healthcare monitoring, unveiling a path to diverse applications. Our study addresses challenges and unlocks possibilities for materials that can adapt, withstand, and sense in innovative ways. © 2024 Society of Chemical Industry.

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纤维素纳米复合韧性水凝胶：协同自愈合、粘合和应变敏感特性

最近，在模拟人体皮肤功能的导电水凝胶方面取得了显著进展。然而，一项重大挑战依然存在：如何制作出一种集自愈合、强大的机械强度和优异的电气特性于一体的导电凝胶。我们的创新在于通过聚合物网络中的纤维素晶体和酸处理多壁碳纳米管（MWCNTs）之间的多重配位键来实现一种强度高、重量轻、可固化的凝胶。嵌入的 MWCNT 在多孔结构中起着动态桥梁的作用，具有优异的机械性能。可逆的配位相互作用带来了显著的恢复能力和可靠的机械与电气自愈能力。此外，这些离子凝胶还可作为适应性强的应力传感器，检测手指和关节运动等重要动作。这项工作介绍了含有多壁碳纳米管的纳米材料，它们具有良好的伸展性、高离子导电性、显著的自愈性和良好的应力敏感性。这些特性为电子传感器、可穿戴设备和医疗保健监测带来了希望，为各种应用开辟了道路。我们的研究解决了材料所面临的挑战，并开启了材料以创新方式适应、承受和感知的可能性。本文受版权保护，保留所有权利。

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来源期刊

Polymer International 化学-高分子科学

CiteScore

7.10

自引率

3.10%

发文量

135

审稿时长

4.3 months

期刊介绍： Polymer International (PI) publishes the most significant advances in macromolecular science and technology. PI especially welcomes research papers that address applications that fall within the broad headings Energy and Electronics, Biomedical Studies, and Water, Environment and Sustainability. The Journal’s editors have identified these as the major challenges facing polymer scientists worldwide. The Journal also publishes invited Review, Mini-review and Perspective papers that address these challenges and others that may be of growing or future relevance to polymer scientists and engineers.