Lightweight and Strong Cellulosic Triboelectric Materials Enabled by Cell Wall Nanoengineering

As intelligent technology surges forward, wearable electronics have emerged as versatile tools for monitoring health and sensing our surroundings. Among these advancements, porous triboelectric materials have garnered significant attention for their lightness. However, these materials face the chall...

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Veröffentlicht in:	Nano letters 2024-03, Vol.24 (10), p.3273-3281
Hauptverfasser:	Li, Xiuzhen, Wang, Jinlong, Liu, Yanhua, Zhao, Tong, Luo, Bin, Liu, Tao, Zhang, Song, Chi, Mingchao, Cai, Chenchen, Wei, Zhiting, Zhang, Puyang, Wang, Shuangfei, Nie, Shuangxi
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Schlagworte:	Cell Wall Electronics Humans Motion Porosity Wearable Electronic Devices
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creator	Li, Xiuzhen Wang, Jinlong Liu, Yanhua Zhao, Tong Luo, Bin Liu, Tao Zhang, Song Chi, Mingchao Cai, Chenchen Wei, Zhiting Zhang, Puyang Wang, Shuangfei Nie, Shuangxi
description	As intelligent technology surges forward, wearable electronics have emerged as versatile tools for monitoring health and sensing our surroundings. Among these advancements, porous triboelectric materials have garnered significant attention for their lightness. However, these materials face the challenge of improving structural stability to further enhance the sensing accuracy of triboelectric sensors. In this study, a lightweight and strong porous cellulosic triboelectric material is designed by cell wall nanoengineering. By tailoring of the cell wall structure, the material shows a high mechanical strength of 51.8 MPa. The self-powered sensor constructed by this material has a high sensitivity of 33.61 kPa–1, a fast response time of 36 ms, and excellent pressure detection durability. Notably, the sensor still enables a high sensing performance after the porous cellulosic triboelectric material exposure to 200 °C and achieves real-time feedback of human motion, thereby demonstrating great potential in the field of wearable electronic devices.
doi_str_mv	10.1021/acs.nanolett.4c00458
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subjects	Cell Wall Electronics Humans Motion Porosity Wearable Electronic Devices
title	Lightweight and Strong Cellulosic Triboelectric Materials Enabled by Cell Wall Nanoengineering
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