摩擦电效应
接触带电
材料科学
静电感应
电介质
能量收集
光电子学
单层
电荷密度
表面改性
纳米技术
接触角
静电学
烷基
接触面积
纳米发生器
电荷(物理)
机械能
接地
表面电荷
静电
分子动力学
图层(电子)
电荷
功率密度
表面能
化学工程
化学物理
可再生能源
曲面(拓扑)
密度泛函理论
表面工程
电势能
电气化
储能
复合材料
作者
Qiqi Ming,Rongbing Han,Yan Xia,P Chen,Xu Zhang,Cuiying Ye,Tao Jiang
出处
期刊:Small
[Wiley]
日期:2026-06-09
卷期号:: e74123-e74123
摘要
ABSTRACT Liquid‐solid triboelectric nanogenerators (LS‐TENGs) based on contact electrification and electrostatic induction effect have garnered significant attention as a promising renewable energy harvesting technology. So far, the LS‐TENGs still have relatively low charge density. Here, we developed a tubular structure LS‐TENG with high charge density by employing a self‐assembled fluoroalkyl layer and grounding water. It was found that the transferred charge of the tubular structure LS‐TENG can be enhanced by grounding water, which is likely attributed to the grounded water acquiring more charges from the ground to effectively shield the dielectric surface charges. Then, applying fluorinated modification on silica (SiO 2 ) surface to enhance surface contact electrification, the tubular LS‐TENG generated a high transferred charge of 1.96 µC (charge density of 2.16 mC m −2 ), superior to previous LS‐TENGs based on contact electrification. The electrical output performance of the tubular LS‐TENGs can be precisely regulated by adjusting the motion frequency, swing angle, and liquid properties. Finally, the tubular LS‐TENGs successfully realized the parallel connection of multiple devices and powered a hygrothermometer, which exhibits great potential in low‐frequency mechanical energy harvesting and self‐powered system applications.
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