材料科学
标度系数
制作
应变计
线性
变形(气象学)
拉伤
共形映射
可扩展性
结构健康监测
过程(计算)
软机器人
可伸缩电子设备
限制
纳米技术
小尺寸
计算机科学
机械工程
可扩展性
材料失效理论
光电子学
测距
航程(航空)
适应性
图像传感器
作者
Longpeng Yang,Zhenlong Huang,Kaixing Yang,Xianwu Tang,Hongwei Xie,Yan Jiang,Tao Chen,Jing Liu,Taisong Pan,Gao Min,Binbin Jiang,Yuan Lin
标识
DOI:10.1002/adma.202515730
摘要
Stretchable strain sensors are capable of accurately mapping deformation across object surfaces, serving as critical components in structural health monitoring and failure mitigation across diverse systems. However, the inherent geometric complexity and non-uniformity of real-world surfaces pose significant challenges to conformal sensor integration. Moreover, conventional strain sensors face inherent trade-offs among sensitivity, detection range, and tunability, limiting their adaptability in practical applications. This study introduces a laser direct writing strategy that combines material and process innovations to enable scalable fabrication of strain sensors on preformed stretchable curved surfaces. Precise control of laser-induced microstructures allows programmable tuning of electromechanical properties, enabling selective behaviors such as high linearity, strain insensitivity, or pronounced resistance changes at small strains. The resulting devices exhibit a high gauge factor of up to 106, a strain detection range exceeding 100%, a minimum detectable strain of 0.1%, and excellent linearity (correlation coefficient > 0.98) within defined operational ranges. As a proof of concept, a sensor array is implemented for strain mapping and deformation reconstruction on a hemispherical 3D stretchable substrate, demonstrating the capability of this approach for high-resolution strain monitoring on complex, non-planar geometries.
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