材料科学
硅橡胶
耐久性
复合材料
灵敏度(控制系统)
可穿戴技术
天然橡胶
接头(建筑物)
纳米复合材料
线性
人工肌肉
炭黑
可穿戴计算机
纳米技术
碳纤维
拉伤
弹性体
数码产品
柔性电子器件
碳纳米管
织物
控制器(灌溉)
图层(电子)
导电体
结构健康监测
氯丁橡胶
钒
硅酮
温度测量
生物相容性材料
粘弹性
补偿(心理学)
聚合物
压阻效应
丝绸
作者
Yunong Zhao,Zhipeng Yuan,Zitian Li,Jinghui Zhang,Xu He,Zihan Wang,Yiting Chen,Jing Gui,Weiqiang Hong,Qi Hong,Xuexi Feng,X. Guo
标识
DOI:10.1021/acsami.5c23728
摘要
As wearable electronics advance toward the development of emerging sensing materials, high-performance integration, and intelligent applications, there is a growing demand for a single flexible sensor capable of comprehensively sensing environmental or physiological conditions. However, achieving high strain sensitivity and precise temperature monitoring remains a significant challenge for flexible dual-mode sensors. Inspired by fish scale textures, a biomimetic structure for a fish-scale-inspired flexible strain/temperature sensor (FSIFSTS) was proposed in this paper. The sensing layer of the FSIFSTS is fabricated as a nanocomposite consisting of multiwalled carbon nanotubes, graphene, and vanadium dioxide within a silicone rubber matrix. FSIFSTS features a 100% strain detection range and a low strain detection limit of 0.5%, along with 6500 cycles of durability within a 40% stretching range. In terms of temperature sensing, FSIFSTS exhibits a high sensitivity of −1.04% °C–1, ultrahigh linearity of 0.9962, and high temperature resolution of 0.5 °C within the 20–90 °C range. Owing to strain and temperature sensing capabilities, FSIFSTS can be applied not only to monitoring human joint movement and guiding rehabilitation training for patients with joint injuries but also to hot compress, high-temperature warnings, and gesture recognition for grasping. Therefore, FSIFSTS shows great potential in fields such as embodied intelligent robot, personalized medical assistance, and real-time human–machine interaction.
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