Wearable Magnetic Field Sensor with Low Detection Limit and Wide Operation Range for Electronic Skin Applications

Li, Shengbin; Wu, Yuanzhao; Asghar, Waqas; Li, Fali; Zhang, Ye; He, Zidong; Liu, Jinyun; Wang, Yuwei; Liao, Meiyong; Shang, Jie; Ren, Long; Du, Yi; Makarov, Denys; Liu, Yiwei; Li, Run‐Wei

doi:10.1002/advs.202304525

Advanced Science

2023

DOI: 10.1002/advs.202304525

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Wearable Magnetic Field Sensor with Low Detection Limit and Wide Operation Range for Electronic Skin Applications

Shengbin Li,

Yuanzhao Wu,

Waqas Asghar

et al.

Abstract: Flexible electronic devices extended abilities of humans to perceive their environment conveniently and comfortably. Among them, flexible magnetic field sensors are crucial to detect changes in the external magnetic field. State‐of‐the‐art flexible magnetoelectronics do not exhibit low detection limit and large working range simultaneously, which limits their application potential. Herein, a flexible magnetic field sensor possessing a low detection limit of 22 nT and wide sensing range from 22 nT up to 400 mT … Show more

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2024

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Cited by 7 publications

References 41 publications

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Contactless User‐Interactive Sensing Display for Human–Human and Human–Machine Interactions

He,

Wei,

et al. 2024

Advanced Materials

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Creating a large‐scale contactless user‐interactive sensing display (CUISD) with optimal features is challenging but crucial for efficient human‐human or human‐machine interactions. This study reports a CUISD based on dynamic alternating current electroluminescence (ACEL) that responds to humidity. Subsecond humidity‐induced luminescence is achieved by integrating a highly responsive hydrogel into the ACEL layer. The patterned silver nanofiber electrode and luminescence layer, produced through electrospinning and microfabrication, result in a stretchable, large‐scale, high‐resolution, multicolor, and dynamic CUISD. The CUISD is implemented for the real‐time control of a remote‐controlled car, wherein the luminescence signals induced by touchless finger movements are distinguished and encoded to deliver specific commands. Moreover, the distinctive recognition of breathing facilitates the CUISD to serve as a visual signal transmitter for information interaction, which is particularly beneficial for individuals with disabilities. The paradigm shift depicted in this work is expected to reshape the way we interact with each other and devices, discovering niche applications in virtual/augmented reality and the metaverse.This article is protected by copyright. All rights reserved

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Contactless User‐Interactive Sensing Display for Human–Human and Human–Machine Interactions

He,

Wei,

et al. 2024

Advanced Materials

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Silicone-polyurea based clear viscoelastic films for flexible displays, impact of diisocyanate, chain extender, soft segment molecular weight, and hard segment contents

Qin,

Xia

2024

European Polymer Journal

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Spintronic devices for biomedical applications

Mostufa,

Liang,

Chugh

et al. 2024

npj Spintronics

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In the past decade, there has been a significant rise in the development of novel spintronic device architectures specifically designed to meet the demands of diverse biomedical applications. These advancements have notably focused on enhancing various bioassay detection techniques, including magnetocardiography and neural signal recording. Through collaboration within the spintronics community, these devices are rapidly transitioning from laboratory prototypes to practical applications, catering to diverse biomedical applications and benefiting both researchers and medical practitioners alike. In this review, we comprehensively explore the biomedical applications of spintronic devices, due to their inherent sensitivity to external magnetic fields, ease of fabrication into large arrays of nano/micro-sized devices within confined spaces, resilience under harsh environmental conditions, and high repeatability. Established spintronics devices that exploit various magnetoresistive effects have already been extensively deployed as magnetic biosensors for disease diagnosis, medical imaging, and bio-magnetic field detection, offering superior sensitivity and robustness. This review aims to provide peers with an up-to-date overview of spintronic devices in biomedical contexts while also commenting on future research trends and challenges. With advancements in nano/microfabrication techniques enhancing device robustness and magnetic field sensitivity, it is foreseeable that these spintronic devices could catalyze revolutionary transformations in healthcare.

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Wearable Magnetic Field Sensor with Low Detection Limit and Wide Operation Range for Electronic Skin Applications

Cited by 7 publications

References 41 publications

Contactless User‐Interactive Sensing Display for Human–Human and Human–Machine Interactions

Contactless User‐Interactive Sensing Display for Human–Human and Human–Machine Interactions

Silicone-polyurea based clear viscoelastic films for flexible displays, impact of diisocyanate, chain extender, soft segment molecular weight, and hard segment contents

Spintronic devices for biomedical applications

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