ZnO based triboelectric nanogenerator on textile platform for wearable sweat sensing application

Here we report the fabrication of textile based wearable sweat sensor working under the principle of triboelectrification. Single electrode triboelectric nanogenerator (STENG) composed of chemically grown zinc oxide (ZnO) nanorods on textile platform has been explored for sweat sensing application. It has been found that the STENG can be operated through biomechanical movements to work as motion sensor. Again, the incremental nature of the output of the STENG under the variation in saline water concentration, signifies the applicability of the same as sweat sensor. It has been proposed that the attachment of hydrated Cl ions of saline water upon attachment with the physisorbed water molecule of ZnO, increases the conduction band electron in ZnO. Consequently, the amount of charge transfer between ZnO and counter triboelectric layer increases and thus yields higher output voltage. To find the efficacy of the system for practical sweat sensing application, miniaturized proof of concept prototype of the STENG (- 1 cm diameter) has been developed and is found to be efficient in sweating condition upon attaching to human body. The fabricated prototype is found to exhibit a sensitivity of - 0.02 V/mu L, along with a detection limit of - 4.8 mu L. Further, upon attaching the prototypes of motion sensor and sweat sensor to a shoe insole, the detection of sweat under foot movement has been demonstrated. Finally, the remote sensing of the signals generated by the textile based STENG has been demonstrated upon integrating it to a microcontroller unit and transmitting the output wirelessly to an electronic gadget.

Automated summary

This study reports the fabrication of a textile-based wearable sweat sensor utilizing the principle of triboelectrification. The single electrode triboelectric nanogenerator (STENG) composed of zinc oxide (ZnO) nanorods on a textile platform was explored for sweat sensing application, showing promising results in terms of motion sensing and sensitivity to changes in saline water concentration. A miniaturized proof of concept prototype of the STENG was developed and found to be efficient in sweating conditions when attached to the human body. Additionally, the integration of the textile-based STENG with a microcontroller unit enabled remote sensing of the generated signals.