High-performance stretchable strain sensors based on auxetic fabrics for human motion detection
High-performance stretchable strain sensors based on auxetic fabrics for human motion detection
Wearable strain sensors play a pivotal role in real-time human motion detection and health monitoring. Traditional fabric-based strain sensors, typically with a positive Poisson's ratio, face challenges in maintaining sensitivity and comfort during human motion due to conflicting resistance changes in different strain directions. In this work, high-performance stretchable strain sensors are developed based on graphene-modified auxetic fabrics (GMAF) for human motion detection in smart wearable devices. The proposed GMAF sensors, with a negative Poisson's ratio achieved through commercially available warp-knitting technology, exhibit an 8-fold improvement in sensitivity compared to conventional plain fabric sensors. The unique auxetic fabric structure enhances sensitivity by synchronizing resistance changes in both wale and course directions. The GMAF sensors demonstrate excellent washability, showing only slight degradation in auxeticity and an acceptable increase in resistance after 10 standard wash cycles. The GMAF sensors maintain stability under different strain levels and various motion frequencies, emphasizing their dynamic performance. The sensors exhibit superior conformability to joint movements, which effectively monitor a full range of motions, including joint bending, sports activities, and subtle actions like coughing and swallowing. The research underscores a promising approach to achieve industrial-scale production of wearable sensors with improved performance and comfort through fabric structure design.
auxetic fabric structures, fabric structure design, negative Poisson’s ratio, sensitivity, stretchable strain sensors, textile sensors, wearable electronics
49845-49855
Zhang, Minglonghai
8b48a29b-7a0a-4351-a2f4-d928ce3ef7ec
Yang, Yadie
aadca357-51bd-4815-b936-6fdf877d203e
Hu, Huiming
c9efed3f-56a4-46fd-9c2b-2d5ed8dcfa93
Zhao, Shuaiquan
22a29b55-c89e-418e-8d44-20a50fd67a23
Song, Wenfang
7822b084-9f20-4503-8000-b1cc2bde6e21
Karim, Nazmul
31555bd6-2dc7-4359-b717-3b2fe223df36
Hu, Hong
98125c12-0ca1-4c9e-bfb0-634c675a7de6
9 September 2024
Zhang, Minglonghai
8b48a29b-7a0a-4351-a2f4-d928ce3ef7ec
Yang, Yadie
aadca357-51bd-4815-b936-6fdf877d203e
Hu, Huiming
c9efed3f-56a4-46fd-9c2b-2d5ed8dcfa93
Zhao, Shuaiquan
22a29b55-c89e-418e-8d44-20a50fd67a23
Song, Wenfang
7822b084-9f20-4503-8000-b1cc2bde6e21
Karim, Nazmul
31555bd6-2dc7-4359-b717-3b2fe223df36
Hu, Hong
98125c12-0ca1-4c9e-bfb0-634c675a7de6
Zhang, Minglonghai, Yang, Yadie, Hu, Huiming, Zhao, Shuaiquan, Song, Wenfang, Karim, Nazmul and Hu, Hong
(2024)
High-performance stretchable strain sensors based on auxetic fabrics for human motion detection.
ACS Applied Materials and Interfaces, 16 (37), .
(doi:10.1021/acsami.4c13402).
Abstract
Wearable strain sensors play a pivotal role in real-time human motion detection and health monitoring. Traditional fabric-based strain sensors, typically with a positive Poisson's ratio, face challenges in maintaining sensitivity and comfort during human motion due to conflicting resistance changes in different strain directions. In this work, high-performance stretchable strain sensors are developed based on graphene-modified auxetic fabrics (GMAF) for human motion detection in smart wearable devices. The proposed GMAF sensors, with a negative Poisson's ratio achieved through commercially available warp-knitting technology, exhibit an 8-fold improvement in sensitivity compared to conventional plain fabric sensors. The unique auxetic fabric structure enhances sensitivity by synchronizing resistance changes in both wale and course directions. The GMAF sensors demonstrate excellent washability, showing only slight degradation in auxeticity and an acceptable increase in resistance after 10 standard wash cycles. The GMAF sensors maintain stability under different strain levels and various motion frequencies, emphasizing their dynamic performance. The sensors exhibit superior conformability to joint movements, which effectively monitor a full range of motions, including joint bending, sports activities, and subtle actions like coughing and swallowing. The research underscores a promising approach to achieve industrial-scale production of wearable sensors with improved performance and comfort through fabric structure design.
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Published date: 9 September 2024
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Publisher Copyright:
© 2024 American Chemical Society.
Keywords:
auxetic fabric structures, fabric structure design, negative Poisson’s ratio, sensitivity, stretchable strain sensors, textile sensors, wearable electronics
Identifiers
Local EPrints ID: 495614
URI: http://eprints.soton.ac.uk/id/eprint/495614
ISSN: 1944-8244
PURE UUID: fe1b2eae-bbba-4f17-b268-578bca0a559a
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Date deposited: 19 Nov 2024 17:42
Last modified: 21 Nov 2024 03:11
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Contributors
Author:
Minglonghai Zhang
Author:
Yadie Yang
Author:
Huiming Hu
Author:
Shuaiquan Zhao
Author:
Wenfang Song
Author:
Nazmul Karim
Author:
Hong Hu
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