Ultra-antifreeze, ultra-stretchable, transparent, and conductive hydrogel for multi-functional flexible electronics as strain sensor and triboelectric nanogenerator

自愈水凝胶 材料科学 纳米发生器 摩擦电效应 数码产品 柔性电子器件 纳米技术 耐久性 石墨烯 灵活性(工程) 聚乙烯醇 复合材料 电气工程 压电 工程类 高分子化学 统计 数学
作者
Xinhuan Dai,Yong Long,Bing Jiang,Wenbin Guo,Wei Sha,Jiangwen Wang,Zifeng Cong,Jiwei Chen,Bingjun Wang,Weiguo Hu
出处
期刊:Nano Research [Springer Science+Business Media]
卷期号:15 (6): 5461-5468 被引量:64
标识
DOI:10.1007/s12274-022-4153-5
摘要

Conductive hydrogels have become one of the most promising candidates for flexible electronics due to their excellent mechanical flexibility, durability of deformation, and good electrical conductivity. However, in real applications, severe environments occur frequently, such as extremely cold weather. General hydrogels always lack anti-freeze and anti-dehydration abilities. Consequently, the functions of electronic devices based on traditional hydrogels will quickly fail in extreme environments. Therefore, the development of environmentally robust hydrogels that can withstand extremely low temperatures, overcome dehydration, and ensure the stable operation of electronic devices has become increasingly important. Here, we report a kind of graphene oxide (GO) incorporated polyvinyl alcohol-polyacrylamide (PVA-PAAm) double network hydrogel (GPPD-hydrogel) which shows excellent anti-freeze ability. The GPPD-hydrogel exhibits not only good flexibility and ultra-high stretchability up to 2,000%, but ensures a high sensitivity when used as the strain sensor at −50 °C. More importantly, when serving as the electrode of a sandwich-structural triboelectric nanogenerator (TENG), the GPPD-hydrogel endows the TENG high and stable output performances even under −80 °C. Besides, the GPPD-hydrogel is demonstrated long-lasting moisture retention over 100 days. The GPPD-hydrogel provides a reliable and promising candidate for the new generation of wearable electronics.

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