A selectively bimodal flexible sensor based on IL/SWCNTs/PEDOT:PSS nanocomposites for materials and shape recognition

Flexible tactile sensors have attracted much attention since they can imitate the sensory functions of the human hand skin, showing conceivable applications in humanoid robots, human-machine interactions and so on. Unfortunately, the practical performance of these sensors is restricted by the drawback of inconvenient-multifunctional responses, such as force and temperature-derived bimodal signals with high coupling that need to be decoupled via complex algorithms. Herein, in this study, a novel IL/SWCNTs/PEDOT:PSS nanocomposite film was fabricated and has a Seebeck coefficient of 29.1 mu V K-1 and an electrical conductivity of 8448 S m-1, in which PEDOT:PSS forms a stable flexible matrix, SWCNTs provide a continuous conductive network, and the incorporation of IL plays dual roles in promoting the dispersion uniformity of SWCNTs and the phase separation of PEDOT:PSS. Furthermore, via the piezoresistive mechanism and thermoelectric output principle, this nanocomposite film derived dual-modal flexible tactile sensor was endowed with the comprehensive features of pressure and temperature response behaviors without any mutual coupling manner, manifesting the skin-like functions of selective sensing capability. Finally, this flexible device is integrated into a humanoid hand for accurately distinguishing the materials and shapes of objects, demonstrating a recognition accuracy of over 98% via the aid of a machine-learning strategy. It can be believed that this study will inspire the development of next-generation biomimetic robots with tactile perception. Inspired by the function of human skin, a flexible tactile sensor was assembled based on the novel IL/SWCNT/PEDOT:PSS nanocomposite, which possesses the multisensory ability to independently identify pressure and temperature with no cross-coupling.