Flexible strain sensors fabricated using carbon-based nanomaterials: A review

• Published in: Current opinion in solid state & materials science Vol. 22; no. 6; pp. 213 - 228
• Main Authors: Yan, Tao, Wang, Zhe, Pan, Zhi-Juan
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.12.2018
• Subjects: Carbon-based nanomaterials; Fabrication process; Nanostructures; Strain sensors; Carbon-based nanomaterials; Nanostructures; Strain sensors; Fabrication process
• ISSN: 1359-0286
• DOI: 10.1016/j.cossms.2018.11.001

•Current development of flexible strain sensors based on carbon nanomaterials was presented.•The assembly structures of carbon-based nanomaterials in polymers were described.•The different carbon-based nanomaterials for flexible strain sensors were compared.•The relationships between the sensing performances and assembly methods were analyzed. Flexible strain sensors have experienced growing demand due to their several potential applications, such as personalized health monitoring, human motion detection, structural health monitoring, smart garments, and robots. Recently, several academic results have been reported concerning flexible and stretchable strain sensors. These reports indicate that the materials and design methods have an important influence on the performance of strain sensors. Carbon-based nanomaterials including carbon-based nanofibers, carbon nanotubes, graphene, and carbon black nanoparticles play a key role in the fabrication of flexible strain sensors with excellent properties. In terms of design, carbon-based nanomaterials are generally combined with polymers to maintain the flexibility and stability of a strain sensor. Various combined methods were successfully developed using different assembly structures of carbon-based nanomaterials in polymers, such as uniform mixing and ordered structures, including films, fibers, nanofiber membranes, yarns, foams, and fabrics. The working mechanisms of the flexible strain sensors, including changing the conductive network between overlapped nanomaterials, tunneling effect, and crack propagation, are also different compared with that of traditional semiconductor and metal sensors. The effects of the carbon-based nanomaterial structures in polymers on the strain sensing performance have been comprehensively studied and analyzed. The potential applications of flexible strain sensors and current challenges have been summarized and evaluated. This review provides some suggestions for further development of flexible and stretchable strain sensors with outstanding performance.