基于自催化Fe3+/TA体系的具有自修复和可回收性的多功能水凝胶，可用于可持续电子皮肤应用。

IF 6.1 1区化学 Q1 CHEMISTRY, ANALYTICAL

Talanta Pub Date : 2026-01-01 Epub Date: 2025-06-30 DOI:10.1016/j.talanta.2025.128531

Chenhao Wang, Qing Xin, Shangqing Liang, Jun Lin, Baidong Yao, Guoqing Yang

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引用次数: 0

摘要

基于水凝胶的电子皮肤材料由于能够模拟人类皮肤的感觉能力和具有与皮肤相当的机械性能而引起了极大的关注。当用作附着在皮肤上的传感器时，水凝胶不可避免地会受到损伤，这突出了对自我修复特性的需求。此外，传统水凝胶传感器缺乏可回收性，不利于可持续发展。为了解决这一问题，我们开发了一种基于多个非共价键和铁离子/单宁酸氧化还原体系的水凝胶，并结合聚乙烯醇作为增强骨架和低聚合的聚丙烯酸。这种设计使水凝胶具有优异的自愈性能，易于回收，提高了机械性能。此外，作为应变传感器，它具有竞争力的性能，包括高灵敏度，快速响应时间和优异的传感稳定性。凭借这些显著的特性，水凝胶显示出作为可持续电子皮肤应用传感器的巨大潜力。

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Multifunctional hydrogel with self-healing and recyclability based on self-catalytic Fe³⁺/TA system for sustainable E-skin application.

Hydrogel-based materials for e-skin applications have aroused tremendous attention due to their ability to simulate human skin's sensory capabilities and possess mechanical properties comparable to those of skin. When used as sensors attached to the skin, hydrogels are inevitably subject to damage, highlighting the need for self-healing properties. Furthermore, the lack of recyclability in traditional hydrogel sensors is detrimental to sustainability. To address this issue, we developed a hydrogel based on multiple noncovalent bonds and ferric ion/tannic acid redox system, combined with polyvinyl alcohol as a reinforcing skeleton and low polymerization of polyacrylic acid. This design endows the hydrogel with excellent self-healing properties, easy recyclability and enhanced mechanical properties. Additionally, as a strain sensor, it exhibits competitive performance including high sensitivity, rapid response time and excellent sensing stability. With these remarkable characteristics, the hydrogel demonstrates significant potential as a sensor for sustainable e-skin applications.

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来源期刊

Talanta 化学-分析化学

CiteScore

12.30

自引率

4.90%

发文量

861

审稿时长

29 days

期刊介绍： Talanta provides a forum for the publication of original research papers, short communications, and critical reviews in all branches of pure and applied analytical chemistry. Papers are evaluated based on established guidelines, including the fundamental nature of the study, scientific novelty, substantial improvement or advantage over existing technology or methods, and demonstrated analytical applicability. Original research papers on fundamental studies, and on novel sensor and instrumentation developments, are encouraged. Novel or improved applications in areas such as clinical and biological chemistry, environmental analysis, geochemistry, materials science and engineering, and analytical platforms for omics development are welcome. Analytical performance of methods should be determined, including interference and matrix effects, and methods should be validated by comparison with a standard method, or analysis of a certified reference material. Simple spiking recoveries may not be sufficient. The developed method should especially comprise information on selectivity, sensitivity, detection limits, accuracy, and reliability. However, applying official validation or robustness studies to a routine method or technique does not necessarily constitute novelty. Proper statistical treatment of the data should be provided. Relevant literature should be cited, including related publications by the authors, and authors should discuss how their proposed methodology compares with previously reported methods.