自愈
材料科学
石墨烯
拉伤
复合材料
自愈水凝胶
纳米技术
高分子化学
医学
内科学
病理
替代医学
作者
Wei Sheng,Jianxin Zhou,Wentao Li,Wenjie Xu,Yuxi Jia,Tao Zhang,Weibo Wang
标识
DOI:10.1021/acsanm.4c06895
摘要
Hydrogels exhibit mechanical properties very similar to biological skin, rendering them promising candidates for electronic skin (e-skin) sensors. However, these materials suffer from significant temperature-induced electrical drift and unstable interfacial contact with metallic electrodes. In this study, we employ elastic graphene foam as electrodes to realize a fully flexible hydrogel device architecture. By designing straight-line and serpentine hydrogel geometries, we enable temperature self-calibration during strain measurements. The resulting hydrogel sensor demonstrates exceptional performance, including constant strain sensitivity (GF = 2.44 with linearity R2 = 0.9999), rapid strain dynamic response (70 ms), low strain detection limit (0.05%), and low temperature drift. This approach not only addresses critical limitations in hydrogel-based sensing platforms but also establishes a robust framework for developing more reliable and versatile flexible sensors.
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