材料科学
可穿戴计算机
灵敏度(控制系统)
自愈水凝胶
纳米技术
生物相容性材料
计算机科学
无线传感器网络
无线
复合数
可穿戴技术
极限(数学)
拉伤
弹性体
生物传感器
多孔性
导电体
远程病人监护
聚合
软质材料
压力传感器
聚合物
人体运动
可扩展性
检出限
匹配移动
作者
Long Yu,Yi’na Yang,Tianran Zhao,Liyang Zhao,Jia Qing Chen,Chunna Yu,Chang Zhao,Guangjian Xing
标识
DOI:10.1021/acsaelm.5c02355
摘要
As biocompatible soft materials with stimuli-responsive characteristics, wearable strain sensors based on conductive hydrogels hold substantial promise across diverse engineering fields. However, their practical applications are often hindered by limited sensitivity and issues related to single functionality. This study presents a multifunctional composite hydrogel composed of PAA/PVA/PEDOT:PSS/Ti3C2TX designed for flexible strain sensors and synthesized through a straightforward one-pot polymerization technique. The incorporation of Ti3C2TX MXene nanosheets significantly enhances the porous architecture and mechanical properties of the hydrogel. This hydrogel features a combination of covalent and physical cross-linking networks, showcasing remarkable elastic recovery, puncture resistance, stretchability, robust interfacial adhesion, and self-healing capabilities. The hydrogel-based strain sensor demonstrates exceptional performance, including high sensitivity (GF = 21.36 in the 31–50% strain range), a low detection limit (53.0 Pa), rapid response and recovery times (42 ms/38 ms), and long-term stability (>1,600 cycles). Its practical applications in information encryption, handwriting recognition, and wireless robotic motion monitoring highlight its potential as a versatile platform for advanced flexible sensing technologies.
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