材料科学
纳米技术
压力传感器
人体皮肤
电子皮肤
联锁
生物医学工程
复合材料
机械工程
遗传学
医学
生物
工程类
作者
Kang Wang,Zheng Lou,Lili Wang,Lianjia Zhao,Shufang Zhao,Dongyi Wang,Han Wu,Kai Jiang,Guozhen Shen
出处
期刊:ACS Nano
[American Chemical Society]
日期:2019-07-22
卷期号:13 (8): 9139-9147
被引量:315
标识
DOI:10.1021/acsnano.9b03454
摘要
Achieving high deformability in response to minimal external stimulation while maximizing human–machine interactions is a considerable challenge for wearable and flexible electronics applications. Various natural materials or living organisms consisting of hierarchical or interlocked structures exhibit combinations of properties (e.g., natural elasticity and flexibility) that do not occur in conventional materials. The interlocked epidermal–dermal microbridges in human skin have excellent elastic moduli, which enhance and amplify received tactile signal transport. Herein, we use the sensing mechanisms inspired by human skin to develop Ti3C2/natural microcapsule biocomposite films that are robust and deformable by mimicking the micro/nanoscale structure of human skin—such as the hierarchy, interlocking, and patterning. The interlocked hierarchical structures can be used to create biocomposite films with excellent elastic moduli (0.73 MPa), capable of high deformability in response to various external stimuli, as verified by employing theoretical studies. The flexible sensor with a hierarchical and interlocked structure (24.63 kPa–1) achieves a 9.4-fold increase in pressure sensitivity compared to that of the planar structured Ti3C2-based flexible sensor (2.61 kPa–1). This device also exhibits a rapid response rate (14 ms) and good cycling reproducibility and stability (5000 times). In addition, the flexible pressure device can be used to detect and discriminate signals ranging from finger motion and human pulses to voice recognition.
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