材料科学
压阻效应
生物相容性
纳米技术
基质(水族馆)
电子皮肤
纳米复合材料
聚乙烯醇
软机器人
图层(电子)
人工肌肉
复合材料
生物电子学
生物传感器
执行机构
计算机科学
冶金
人工智能
地质学
海洋学
作者
Shohreh Azadi,Shuhua Peng,Sajad A. Moshizi,Mohsen Asadnia,Jiangtao Xu,Inkyu Park,Chunhui Wang,Shuying Wu
标识
DOI:10.1002/admt.202000426
摘要
Abstract Hydrogel‐based strain sensors have attracted considerable interest for applications such as skin‐like electronics for human motion detection, soft robotics, and human–machine interfaces. However, fabrication of hydrogel strain sensors with desirable mechanical and piezoresistive properties is still challenging. Herein, a biocompatible hydrogel sensor is presented, which is made of polyvinyl alcohol (PVA) nanocomposite with high stretchability up to 500% strain, high mechanical strength of 900 kPa, and electrical conductivity (1.85 S m ‐1 ) comparable to human skin. The hydrogel sensors demonstrate excellent linearity in the whole detection range and great durability under cyclic loading with low hysteresis of 7%. These excellent properties are believed to be contributed by a new bilayer structural design, i.e., a thin, conductive hybrid layer of PVA/silver nanowires (AgNWs) deposited on a pure strong PVA substrate. PVA solution of high concentration is used to fabricate the substrate while the top layer consists of dilute PVA solution so that high content of AgNWs can be dispersed to achieve high electrical conductivity. Together with a rapid response time (0.32 s) and biocompatibility, this new sensor offers great potential as a wearable sensor for epidermal sensing applications, e.g., detecting human joint and muscle movements.
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