Performance Deficiency Improvement of CNT-Based Strain Sensors by Magnetic-Induced Patterning

材料科学 碳纳米管 降级(电信) 纳米技术 机制(生物学) 拉伤 纳米线 计算机科学 医学 电信 认识论 内科学 哲学
作者
Na Li,Gui‐Wen Huang,Yu Liu,Cheng‐Bing Qu,Meng Li,Hong‐Mei Xiao
出处
期刊:ACS Applied Materials & Interfaces [American Chemical Society]
卷期号:15 (4): 5774-5786 被引量:11
标识
DOI:10.1021/acsami.2c18036
摘要

As one of the most promising candidates, ubiquitous cycling degradation seriously affects the accuracy of carbon nanotube (CNT)-based sensors, and the reason for which is still unclear. Herein, the cycling degradation mechanism of CNT-based strain sensors has been detected by comparatively investigating the difference between the sensing behavior of CNT- and silver nanowire (Ag-NW)-based sensors, from which the microcrack-disconnection and unfolding-tunneling effects have been clarified as the sensing mechanism for Ag-NWs and CNT-based strain sensors, respectively. Furthermore, sliding and unfolding behaviors resulting from the weak interaction between CNTs have been proven to cause degradation. Correspondingly, a creative magnetically induced patterning method is proposed by utilizing magnetic nanoparticles as obstacles to prevent the CNTs from relative sliding. Benefiting from the advantageous factor, the performance deficiency of the CNT-based sensor has been overcome, and the sensitivity was significantly improved up to 5.2 times with accurate human activity detection. The competitive sensing performance of the CNTs demonstrates the reference value of the deficiency mechanism and solution scheme obtained in this study.

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