College of Chemical Engineering and Pharmaceutics, Henan University of Science and Technology, Luoyang, Henan 471023, P. R. China.
Key Laboratory of Materials Processing and Mold (Zhengzhou University), Ministry of Education, National Engineering Research Center for Advanced Polymer Processing Technology, Zhengzhou University, Zhengzhou, Henan 450002, P. R. China.
ACS Appl Mater Interfaces. 2021 Apr 7;13(13):15572-15583. doi: 10.1021/acsami.0c22823. Epub 2021 Mar 24.
High-performance flexible strain sensors are urgently needed with the rapid development of wearable intelligent electronics. Here, a bifiller of carbon nanotubes (CNTs) and graphene (GR) for filling flexible porous polydimethylsiloxane (CNT-GR/PDMS) nanocomposites is designed and prepared for strain-sensing applications. The typical microporous structure was successfully constructed using the Soxhlet extraction technique, and the connected CNTs and GR constructed a perfect three-dimensional conductive network in the porous skeleton. As a result, the stretchability and sensitivity of the CNT-GR/PDMS-based strain sensors were well regulated based on the porous structure and the typical synergistic conductive network. Based on the destruction effect of the brittle synergistic conductive network located in the outer and inner layers of the cell skeleton and the contact effect between adjacent cells in different strain ranges, the prepared CNTs-GR/PDMS-based strain sensor exhibited superior gauge factors of 182.5, 45.6, 70.2, and 186.5 in the 0-3, 3-57, 57-90, and 90-120% strain regions, respectively. In addition, this material also exhibited an ultralow detection limit (0.5% strain), a fast response time (60 ms), good stability and durability (10,000 cycles), and frequency-/strain-dependent sensing performances, making it active for the detection of various external environments. Finally, the prepared porous CNTs-GR/PDMS-based strain sensor was attached to the skin to detect various human motions, such as wrist bending, finger bending, elbow bending, and knee bending, thereby demonstrating wide application prospects in smart wearable devices.
随着可穿戴智能电子产品的快速发展,人们迫切需要高性能的柔性应变传感器。在这里,设计并制备了一种用于应变传感应用的碳纳米管(CNT)和石墨烯(GR)双填充剂填充柔性多孔聚二甲基硅氧烷(CNT-GR/PDMS)纳米复合材料。采用索氏提取技术成功构建了典型的微孔结构,而相互连接的 CNT 和 GR 在多孔骨架中构建了完美的三维导电网络。因此,基于多孔结构和典型的协同导电网络,调节了 CNT-GR/PDMS 基应变传感器的拉伸性和灵敏度。基于位于细胞骨架内外层的脆性协同导电网络的破坏效应以及不同应变范围内相邻细胞之间的接触效应,所制备的 CNT-GR/PDMS 基应变传感器在 0-3、3-57、57-90 和 90-120%应变区域分别表现出 182.5、45.6、70.2 和 186.5 的优异应变系数。此外,这种材料还表现出超低检测限(0.5%应变)、快速响应时间(60 ms)、良好的稳定性和耐用性(10000 次循环)以及频率/应变相关的传感性能,使其可用于检测各种外部环境。最后,将制备的多孔 CNT-GR/PDMS 基应变传感器附着在皮肤上,以检测各种人体运动,如手腕弯曲、手指弯曲、肘部弯曲和膝盖弯曲,从而在智能可穿戴设备中具有广泛的应用前景。
