Surface-microengineering for high-performance triboelectric tactile sensor via dynamically assembled ferrofluid template

Surface-microengineering of the active layer in triboelectric tactile sensor enables to effectively reduce the surface stiffness of the non-ideal planar triboelectric film and increase the contact area during the triboelectric process. In this work, a facile and dynamically controllable two-step method based on the unique characteristic of ferrofluid has been proposed to fabricate a high-performance self-powered triboelectric tactile sensor. Through adjusting the distance and rotating angle of magnet, ferrofluid spikes with different lengths and inclination angles ranging from 30 degrees to 90 degrees can be obtained. The adjustable microstructures distributed on the active layer were analyzed theoretically and verified experimentally, indicating the inclined and high microstructures can effectively facilitate the sensing performance. When the inclination angle of the microstructure is 30 degrees, the sensitivity delivers 6.75 kPa(-1) with pressure lower than 44 kPa, and keeps excellent linearity with the sensitivity of 3.01 kPa(-1) even the detection pressure reaches 250 kPa. Simultaneously, the tactile sensor has a fast response/recovery time of 75 ms and 56 ms, respectively. Finally, it was demonstrated to adopt in the bionics robotic hands for weight perception and attached to various parts of the human body for detecting physiological activities with outstanding repeatability and stability.

Automated summary

In this study, a high-performance self-powered triboelectric tactile sensor was fabricated by utilizing ferrofluid to adjust microstructures for improved sensing performance. The sensor showed fast response/recovery times and excellent repeatability and stability when used in bionics robotic hands and on various parts of the human body for detecting physiological activities.