posted on 2024-01-26, 15:36authored byZhipeng Hu, Wanlong Lu, Youbin Zheng, Jiamei Liu, Hossam Haick, Laju Bu
Enhancing the durability and functionality of existing
materials
through sustainable pathways and appropriate structural design represents
a time- and cost-effective strategy for the development of advanced
wearable devices. Herein, a facile graphene oxide (GO) modification
method via the hydroxyl-yne click reaction is present for the first
time. By the click coupling between propiolate esters and hydroxyl
groups on GO under mild conditions, various functional molecules are
successfully grafted onto the GO. The modified GO is characterized
by FTIR, XRD, TGA, XPS, and contact angle, proving significantly improved
dispersibility in various solvents. Besides the high efficiency, high
selectivity, and mild reaction conditions, this method is highly practical
and accessible, avoiding the need for prefunctionalizations, metals,
or toxic reagents. Subsequently, a rGO-PDMS sponge-based piezoresistive
sensor developed by modified GO-P2 as the sensitive material exhibits
impressive performance: high sensitivity (335 kPa–1, 0.8–150 kPa), wide linear range (>500 kPa), low detection
limit (0.8 kPa), and long-lasting durability (>5000 cycles). Various
practical applications have been demonstrated, including body joint
movement recognition and real-time monitoring of subtle movements.
These results prove the practicality of the methodology and make the
rGO-PDMS sponge-based pressure sensor a real candidate for a wide
array of wearable applications.