压电
材料科学
声学
结构健康监测
生物医学工程
拉伤
波形
灵敏度(控制系统)
触觉传感器
压电传感器
压力传感器
有限元法
脉搏(音乐)
功率(物理)
正常模式
脉冲波
工作(物理)
圆柱
智能材料
层状结构
应变率
传感器
偶极子
作者
Qi Yang,Zhongqian Song,Shengjie Liu,Yingming Ma,Weiyan Li,Huijun Kong,Cuiyu Liu,Yu Bao,Li Niu
标识
DOI:10.1002/advs.202522157
摘要
ABSTRACT High‐fidelity wrist pulse acquisition, essential for the early diagnosis and precise management of cardiovascular diseases, requires tactile sensors with both ultrasensitive and linear electromechanical responses. Biological Pacinian corpuscles transduce mechanical stimuli into localized strain via concentric lamellar architecture, enabling subtle and dynamic perception of pressure fluctuations. Inspired by the working mode of Pacinian corpuscles, this work presents a piezoelectric tactile sensor featuring a multilayer grooved architecture that transduces external pressure into localized in‐plane strain within the piezoelectric layer, effectively enhancing dipole alignment and charge separation. Finite element simulations and experimental results confirm that the grooved architecture contributes to strain concentration, giving rise to an ultrahigh sensitivity of 185 mV·kPa − 1 and linear electromechanical response up to 300 kPa and a power density of 806 µW·cm − 2 . The tactile sensor enables high‐fidelity acquisition of multi‐site pulse waveforms and accurate estimation of blood pressure, facilitating comprehensive cardiovascular assessment via heart rate variability and Poincare analysis. This bioinspired design offers an effective approach to overcoming the intrinsic limitations of piezoelectric materials and holds significant potential for developing high‐performance piezoelectric sensors for continuous, noninvasive health monitoring.
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