Interface engineered silver nanoparticles decorated g-C3N4 nanosheets for textile based triboelectric nanogenerators as wearable power sources

Textile based mechanical energy harvesting devices have emerged out as potential power sources for wearable electronics. For the first time, we report the fabrication of a textile based triboelectric nanogenerator (T-TENG) composed of an active layer of silver (Ag) nanoparticles loaded graphitic carbon nitride (g-C3N4) nanosheets on carbon fibres. The triboelectric characteristics has been found to be dramatically enhanced upon combinatorial effect of Ag nanoparticles loading and interfacial engineering with the introduction of a nylon layer between nanosheets and carbon cloth fibres. With teflon as a counter triboelectric material, under mechanical agitation, the AgCN/nylon bi-layer T-TENG can generate an open circuit voltage of as high as similar to 200 V and charges a commercial capacitor up to similar to 85 V in only 30 s. The improvement in triboelectric characteristics of the AgCN based bi-layer T-TENG is attributed to Ag nanoparticles induced modifications of surface area, dielectric properties and intrinsic resistivity of the host material. Apart from mechanical impact, the T-TENG can generate electrical output under minute mechanical forces originating from sources like air flow and biomechanical actions when integrated to wearable clothing and the output data can be accessed remotely. The AgCN/nylon-teflon based bi-layer T-TENG is not only stable at higher operating temperatures but also exhibits a higher power conversion efficiency at an elevated temperature (up to similar to 65 degrees C), which could be explained by the energetics of the composite system. The superior output characteristics as well as thermal stability of AgCN/nylon based triboelectric nanogenerator makes it a potential candidate for integration into textile based wearable electronic devices.

Automated summary

In this study, a textile-based triboelectric nanogenerator (T-TENG) was developed using silver nanoparticles and a nylon layer. The T-TENG showed enhanced triboelectric characteristics and could generate high voltage and electrical output under mechanical agitation. The T-TENG also exhibited stability at higher operating temperatures and higher power conversion efficiency, making it a potential candidate for integration into textile-based wearable electronic devices.