机械容积
材料科学
光致发光
手语
兴奋剂
智能材料
光电效应
电子材料
声学
光电子学
像素
计算机科学
压电
卷积神经网络
闪烁体
芯(光纤)
发光
符号(数学)
纳米技术
机械工程
领域(数学)
荧光粉
人工智能
触觉传感器
工作(物理)
强度(物理)
光电传感器
作者
Xue Meng,P E Li,Mingxin Zhou,Jinlong Wang,Hao Suo,Guodong Zhang,Xiaojun Wang,Zhijun Wang
摘要
ABSTRACT Advancements in human‐machine interaction technology require flexible sensors to possess core capabilities, including high stability, anti‐interference properties, and self‐powering functionality. Traditional electrical sensors usually struggle to adapt to complex and long‐term application scenarios. Mechanoluminescence (ML) materials present a novel solution to this challenge, yet existing ML materials still suffer from issues such as requiring pre‐radiation charging and insufficient cycling stability. Here, we report a series of self‐recovering near‐infrared (NIR) ML materials—ZnGa 1‐ m Al m InO 4 :Cr 3+ , which possess excellent piezoelectric properties and low cost. By precisely controlling the crystal field strength through adjusting the doping concentration of Al 3+ ions, the photoluminescence intensity was enhanced by 40.65‐fold. Even after undergoing thousands of mechanical stimulation cycles, this self‐healing near‐infrared ML material retains 98% of its initial luminescence intensity. When integrated with photoelectric sensors, ZAIO:Cr 3+ @PDMS demonstrated outstanding performance in sign language recognition (achieving 99.46% accuracy) and intelligent road monitoring through convolutional neural networks. This work provides novel insights for designing NIR ML materials and lays the foundation for integrating ML materials with intelligent neural networks.
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