材料科学
粘弹性
弹性体
微观结构
复合材料
耐久性
灵敏度(控制系统)
压力传感器
导电体
离子键合
缩进
纳米技术
柔性电子器件
脉搏(音乐)
弹性(物理)
流变学
作者
Allen J. Cheng,Wenkai Chang,Zhuohan Cao,Zhao Sha,Shuai He,Ming Xuan Chua,Bingnong Jiang,Yuansen Qiao,Ziyan Gao,Wenkui Dong,Wengui Li,Liao Wu,Dewei Chu,Shuhua Peng
标识
DOI:10.1002/advs.202519398
摘要
Soft ionic conductive elastomers offer unique advantages for super-capacitive pressure sensors, where the electrical double layer (EDL) effect enables high sensitivity and rapid response. However, the roles of microstructure and viscoelasticity on EDL-driven sensing remain poorly understood. This study establishes detailed correlations between elastomer microstructure, intrinsic viscoelastic properties, and sensor performance by integrating mechanical and electrical analyses. Validation of the EDL mechanism reveals how microstructural optimization and viscoelastic tuning enhance sensitivity, linear range, and stability. Height-graded architectures yield a sensor with a sensitivity of 2.70 nF/kPa, a broad linear range of 0-2000 kPa, and robust durability over 10 000 cycles. These devices demonstrate multifunctionality in robotic electronic skin, pressure mapping, and real-time physiological monitoring such as wrist pulse detection. The findings establish key structure-property-performance relationships, providing design guidelines for next-generation, high-performance super-capacitive sensors.
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