材料科学
压电
湿度
声学
复合材料
超声波传感器
灵敏度(控制系统)
压电传感器
传感器
稳健性(进化)
极化
复合数
声表面波
声传感器
声波
相对湿度
电压
纳米发生器
莲花效应
压力(语言学)
光电子学
结构健康监测
联轴节(管道)
机械能
声纳
能量收集
消散
作者
Yu Liu,Sally Yuan,Iqra Shahbaz,Yang Bai,Yanpeng Xue,Y. Luan,Ping Che,Lihong Li
出处
期刊:Small methods
[Wiley]
日期:2025-12-12
卷期号:10 (3): e01879-e01879
标识
DOI:10.1002/smtd.202501879
摘要
To address the long-standing challenges of slow response, weak signal, and poor mechanical robustness in conventional flexible humidity sensors, A novel flexible multifunctional sensor is developed based on a "lotus-leaf acoustic wave collaborative lead-free piezoelectric" technology strategy. Specifically, a lotus leaf surface is used as a template, which is replicated with PVDF and then combined with a cellulose matrix embedded with niobium-based perovskite crystals, resulting in a sandwich-structured, flexible, lead-free piezoelectric composite film. Under acoustic wave excitation, the local piezoelectric coupling at the bio-inspired papilla interfaces significantly accelerates water adsorption/desorption kinetics, achieving an exceptional humidity response/recovery time of 0.98/1.2 s and a high sensitivity of 97%. The sensor demonstrates superior performance compared to commercial hygrometers. In addition, it has a high response signal of 130 V and a voltage sensitivity of 4.33 V N-1 under a stress of 40 N, thus achieving dual parameter sensing. This humidity sensor, with its sub second response, high sensitivity, and dual-mode sensing capability of force and humidity, is expected to capture the slightest humidity and mechanical changes in real-time medical monitoring, motion tracking, and environmental IoT, providing unprecedented secure and green core components for intelligent health, and sustainable sensing systems.
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