Abstract
While triboelectric nanogenerators (TENGs) made of biomaterials are becoming significant components of self-charged monitoring healthcare systems, most of them show low output performance and poor durability. Herein, a surfactant-free graphene oxide-polylactic acid (GO/PLA) nanocomposite with customizable honeycomb patterns was, for the first time, prepared via a scalable two-step solution method to achieve a power-boosted biocompatible TENG. The first step of this method involved using a suitable solvent (such as dimethylformamide) to well disperse the GO nanoparticles into PLA. Subsequently, honeycomb patterns were induced by using a mixture of chloroform and methanol as a suitable volatile solvent/nonsolvent pair for improved phase separation. The results indicated that GO nanoparticles with large surface area and abundant electron-donating groups decorated the honeycomb patterns and significantly influenced the electro-positivity and surface properties of the PLA bio-polymer. An unprecedented antagonistic TENG ( A- TENG) based on the concave-honeycomb GO-PLA ( hc- GO/PLA) and its corresponding convex-polydimethylsiloxane ( c- PDMS) form a pair of tribo-components with antagonistic friction surfaces and generate an output power of 3.25 mW, which is 13.6 times higher than that of a flat-surface TENG ( f -TENG) without GO additives. We believe that the incorporation of functional GO nanoparticles without surfactants expands the potential applications of biocompatible A- TENG in healthcare areas thanks to its boosted output performance and persisting biocompatibility. • A new surfactant-free patterning technique for GO/PLA nanocomposite. • Pattern features are adjusted. • New design of antagonistic TENG for significantly boosting performance. • Bio A- TENG can power wearable electronics.
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More From: Journal of Science: Advanced Materials and Devices
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