Revolutionizing self-powered robotic systems with triboelectric nanogenerators

Triboelectric nanogenerators (TENGs), offering self-powered actuation, grasping, and sensing capabilities without the need for an external power source, have the potential to revolutionize the field of self-powered robotic systems. TENGs can directly convert mechanical energy into electrical energy that can be used to power small electronics. This review explores the huge potential of TENGs' mechanisms and modes for various robotics actuation and sensing applications. Firstly, the improvements in efficiency and reliability of TENG-based actuation systems by self-powered actuation systems are discussed. Following that, TENG-based grippers having controlled gripping power and a distinctive ability to self-calibrate for precise and sharp object handling are enlightened. Additionally, the design and development of TENG-based pressure sensors incorporated into robotic grippers are further discussed. Self-powered multimode-sensing robotic devices, which can sense many stimuli such as temperature, applied force and its direction, and humidity, are briefly discussed. Integrating self-powered robotic systems with human-machine-interaction (HMI) technologies enables more sophisticated and intelligent robotic contact with its external environment, is also highlighted. Finally, we addressed the challenges and future improvements in this emerging field. In conclusion, TENGs can open up a wide range of opportunities for selfpowered actuation, gripping, and sensing with exceptional efficiency and precision while being compatible with both soft and rigid robotic systems.

Automated summary

Triboelectric nanogenerators (TENGs) have the potential to revolutionize self-powered robotic systems by offering self-powered actuation, grasping, and sensing capabilities. TENGs directly convert mechanical energy into electrical energy, powering small electronics. This review explores the mechanisms and modes of TENGs for robotics actuation and sensing applications, discussing improvements in efficiency and reliability, grippers with controlled gripping power and self-calibration abilities, pressure sensors incorporated into robotic grippers, and the integration of self-powered robotic systems with human-machine interaction (HMI) technologies.