Flexible triboelectric nanogenerators using transparent copper nanowire electrodes: energy harvesting, sensing human activities and material recognition

Triboelectric nanogenerators (TENGs) have emerged as a promising green technology to efficiently harvest otherwise wasted mechanical energy from the environment and human activities. However, cost-effective and reliably performing TENGs require rational integration of triboelectric materials, spacers, and electrodes. The present work reports for the first time the use of oxydation-resistant pure copper nanowires (CuNWs) as an electrode to develop a flexible, and inexpensive TENG through a potentially scalable approach involving vacuum filtration and lactic acid treatment. A similar to 6 cm(2) device yields a remarkable open circuit voltage (V-oc) of 200 V and power density of 10.67 W m(-2) under human finger tapping. The device is robust, flexible and noncytotoxic as assessed by stretching/bending maneuvers, corrosion tests, continuous operation for 8000 cycles, and biocompatibility tests using human fibroblast cells. The device can power 115 light emitting diodes (LEDs) and a digital calculator; sense bending and motion from the human hand; and transmit Morse code signals. The robustness, flexibility, transparency, and non-cytotoxicity of the device render it particularly promising for a wide range of energy harvesting and advanced healthcare applications, such as sensorised smart gloves for tactile sensing, material identification and safer surgical intervention.

Automated summary

This study presents a flexible and cost-effective triboelectric nanogenerator (TENG) using oxidation-resistant pure copper nanowires as electrodes. The device demonstrated stable performance with an impressive open circuit voltage of 200 V and power density of 10.67 W m(-2). It is robust, flexible, transparent, and non-cytotoxic, making it promising for various energy harvesting and advanced healthcare applications.