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Literature DB >> 32803872

Cellulose-Based Fully Green Triboelectric Nanogenerators with Output Power Density of 300 W m^-2.

Renyun Zhang¹, Christina Dahlström², Haiyang Zou³, Julia Jonzon¹, Magnus Hummelgård¹, Jonas Örtegren¹, Nicklas Blomquist¹, Ya Yang⁴, Henrik Andersson⁵, Martin Olsen¹, Magnus Norgren², Håkan Olin¹, Zhong Lin Wang^3,4.

Abstract

Triboelectric nanogenerators (TENGs) have attracted increasing attention because of their excellent energy conversion efficiency, the diverse choice of materials, and their broad applications in energy harvesting devices and self-powered sensors. New materials have been explored, including green materials, but their performances have not yet reached the level of that for fluoropolymers. Here, a high-performance, fully green TENG (FG-TENG) using cellulose-based tribolayers is reported. It is shown that the FG-TENG has an output power density of above 300 W m-2 , which is a new record for green-material-based TENGs. The high performance of the FG-TENG is due to the high positive charge density of the regenerated cellulose. The FG-TENG is stable after more than 30 000 cycles of operations in humidity of 30%-84%. This work demonstrates that high-performance TENGs can be made using natural green materials for a broad range of applications.

Entities: Chemical

Keywords: green materials; regenerated cellulose; triboelectric charge densities; triboelectric nanogenerators

Year: 2020 PMID： 32803872 DOI： 10.1002/adma.202002824

Source DB: PubMed Journal: Adv Mater ISSN： 0935-9648 Impact factor: 30.849

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Cited

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