摩擦电效应
复合数
纤维素
制作
材料科学
纳米技术
表面改性
纳米发生器
自愈水凝胶
电导率
可穿戴计算机
可穿戴技术
机械能
复合材料
电极
功率密度
数码产品
电子皮肤
能量收集
作者
Afei Liu,Siyu Zheng,Wenhui Wu,Jiaqing Liu,Hui Zhang,Lihui Chen,Xiaxing Zhou,Kai Liu
标识
DOI:10.1016/j.jobab.2025.08.003
摘要
Multifunctional wearable flexible electronic devices based on hydrogels have received extensive research in recent years. Despite their promising applications, a significant challenge persists in terms of efficiently powering these devices. Triboelectric nanogenerators (TENGs) assembled by surface-modified hydrogels may be one of the promising strategies to address this challenge. This study presents the development of a multifunctional composite hydrogel, which is synthesized through the amino surface modification of glycerin-cellulose hydrogel (3-aminopropyltriethoxysilane-glycerin-cellulose, A-GC). The resulting composite hydrogel is utilized in the fabrication of electrodes of TENGs, which can effectively harvest mechanical energy to power flexible sensors. By using cellulose and glycerin as primary raw materials and 3-aminotriethoxysilane as surface modification components, the composite hydrogel exhibits excellent mechanical properties, coupled with good electrical conductivity (2.83 S/m). More importantly, it exhibits a high triboelectric output performance of 205.3 V, maintains stable long-term triboelectric output, and achieves a maximum triboelectric power density of 732.1 mW/m 2 . Furthermore, the introduction of glycerin into the cellulose hydrogel enhances its mechanical properties and triboelectric output performance even under extreme environmental conditions (–24 and 60 °C). The A-GC-TENG demonstrates significant potential in various applications, including mechanical energy harvesting and conversion, writing recognition, wireless signal transmission, and human-computer interaction, showing great application prospects in flexible wearable sensors and self-powered electronic devices. The development of the composite cellulose hydrogel offers a novel approach for the fabrication of high-performance flexible wearable electronic devices, which is capable of functioning effectively in harsh environments.
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