可穿戴计算机
材料科学
数码产品
巨磁阻
分层(地质)
弯曲
磁场
磁电阻
可穿戴技术
柔性电子器件
纳米技术
电子元件
计算机科学
光电子学
电气工程
嵌入式系统
工程类
复合材料
物理
古生物学
俯冲
量子力学
生物
构造学
作者
Junjie Zhang,Zhenhu Jin,Guangyuan Chen,Jiamin Chen
标识
DOI:10.1038/s41378-024-00716-2
摘要
Abstract In recent years, there has been a significant increase in the prevalence of electronic wearables, among which flexible magnetoelectronic skin has emerged as a key component. This technology is part of the rapidly progressing field of flexible wearable electronics, which has facilitated a new human perceptual development known as the magnetic sense. However, the magnetoelectronic skin is limited due to its low sensitivity and substantial field limitations as a wearable electronic device for sensing minor magnetic fields. Additionally, achieving efficient and non-destructive delamination in flexible magnetic sensors remains a significant challenge, hindering their development. In this study, we demonstrate a novel magnetoelectronic touchless interactive device that utilizes a flexible giant magnetoresistive sensor array. The flexible magnetic sensor array was developed through an electrochemical delamination process, and the resultant ultra-thin flexible electronic system possessed both ultra-thin and non-destructive characteristics. The flexible magnetic sensor is capable of achieving a bending angle of up to 90 degrees, maintaining its performance integrity even after multiple repetitive bending cycles. Our study also provides demonstrations of non-contact interaction and pressure sensing. This research is anticipated to significantly contribute to the advancement of high-performance flexible magnetic sensors and catalyze the development of more sophisticated magnetic electronic skins.
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