Wearable body temperature sensing with autonomous self-regulated joule heating and passive cooling for healthcare applications
Wearable body temperature sensing with autonomous self-regulated joule heating and passive cooling for healthcare applications
The positive temperature coefficient (PTC) effect observed in conductive polymer composites (CPCs) holds significant promise due to its wide materials selection and ability to offer enhanced sensitivity. However, traditional CPCs have relatively high PTC switching temperatures (typically above 100 °C) and are often unsuitable for bodily healthcare devices. This study introduces a novel approach leveraging the synergistic effect of an eco-friendly fatty acid, namely lauric acid (LA), with flexible styrene-ethylene-butylene-styrene (SEBS) thermoplastic elastomer (TPE) as a matrix and graphene nanoplatelets (GNPs) as a conductive filler. The composite film demonstrates exceptional temperature responsiveness at body-relevant temperatures (35–40 °C) with a PTC intensity reaching an unprecedented 4 orders of magnitude, set apart by its fine-tuning ability across a remarkable detecting temperature interval (Maximum temperature coefficient of resistance (TCR): 471.4% °C−1). This advancement is facilitated through a carefully engineered morphology, wherein the distribution of LA significantly influences the conductive network's reformation within the composite, with the in-situ optical microscope used to reveal the reformation of the conductive network structure. The flexible composite demonstrates significant potential for body temperature sensing, self-regulating heating, and passive cooling, paving the way for future developments in eco-friendly, highly sensitive, and flexible sensors in wearable health monitoring and thermotherapy.
flexible nanocomposite, health monitoring, lauric acid, self-regulating joule heating, thermotherapy, wearable temperature sensors
Guo, Hongxu
e065a74f-5791-4d0e-9db5-5c7c8bb499bc
Lu, Lichang
6fb794d4-e20e-4b3b-bd77-89dee25f8534
Hatton, Fiona L.
6e835559-3fd2-4a71-b847-30cac71f9b3c
Xu, Lulu
8daadc9f-cedf-4ae6-beac-0bb0330ca60c
Yu, Eileen
28e47863-4b50-4821-b80b-71fb5a2edef2
Peijs, Ton
e67c6fb5-6405-455d-b8c2-12d8f75ea4b0
Bilotti, Emiliano
4b3b7c04-897c-462d-a19b-c804099998e7
Zhang, Han
be995ae3-ca78-4f48-a3cf-02ed7ed20710
Liu, Yi
3e2d2774-6e78-4634-b406-8716f4595ae9
Guo, Hongxu
e065a74f-5791-4d0e-9db5-5c7c8bb499bc
Lu, Lichang
6fb794d4-e20e-4b3b-bd77-89dee25f8534
Hatton, Fiona L.
6e835559-3fd2-4a71-b847-30cac71f9b3c
Xu, Lulu
8daadc9f-cedf-4ae6-beac-0bb0330ca60c
Yu, Eileen
28e47863-4b50-4821-b80b-71fb5a2edef2
Peijs, Ton
e67c6fb5-6405-455d-b8c2-12d8f75ea4b0
Bilotti, Emiliano
4b3b7c04-897c-462d-a19b-c804099998e7
Zhang, Han
be995ae3-ca78-4f48-a3cf-02ed7ed20710
Liu, Yi
3e2d2774-6e78-4634-b406-8716f4595ae9
Guo, Hongxu, Lu, Lichang, Hatton, Fiona L., Xu, Lulu, Yu, Eileen, Peijs, Ton, Bilotti, Emiliano, Zhang, Han and Liu, Yi
(2025)
Wearable body temperature sensing with autonomous self-regulated joule heating and passive cooling for healthcare applications.
Advanced Functional Materials, 35 (13), [2417961].
(doi:10.1002/adfm.202417961).
Abstract
The positive temperature coefficient (PTC) effect observed in conductive polymer composites (CPCs) holds significant promise due to its wide materials selection and ability to offer enhanced sensitivity. However, traditional CPCs have relatively high PTC switching temperatures (typically above 100 °C) and are often unsuitable for bodily healthcare devices. This study introduces a novel approach leveraging the synergistic effect of an eco-friendly fatty acid, namely lauric acid (LA), with flexible styrene-ethylene-butylene-styrene (SEBS) thermoplastic elastomer (TPE) as a matrix and graphene nanoplatelets (GNPs) as a conductive filler. The composite film demonstrates exceptional temperature responsiveness at body-relevant temperatures (35–40 °C) with a PTC intensity reaching an unprecedented 4 orders of magnitude, set apart by its fine-tuning ability across a remarkable detecting temperature interval (Maximum temperature coefficient of resistance (TCR): 471.4% °C−1). This advancement is facilitated through a carefully engineered morphology, wherein the distribution of LA significantly influences the conductive network's reformation within the composite, with the in-situ optical microscope used to reveal the reformation of the conductive network structure. The flexible composite demonstrates significant potential for body temperature sensing, self-regulating heating, and passive cooling, paving the way for future developments in eco-friendly, highly sensitive, and flexible sensors in wearable health monitoring and thermotherapy.
Text
Adv Funct Materials - 2025 - Guo - Wearable Body Temperature Sensing with Autonomous Self‐regulated Joule Heating and
- Version of Record
More information
e-pub ahead of print date: 2 February 2025
Keywords:
flexible nanocomposite, health monitoring, lauric acid, self-regulating joule heating, thermotherapy, wearable temperature sensors
Identifiers
Local EPrints ID: 499222
URI: http://eprints.soton.ac.uk/id/eprint/499222
ISSN: 1616-301X
PURE UUID: f1fc3505-b96f-4dc2-bba2-a1e0cbcc2e34
Catalogue record
Date deposited: 12 Mar 2025 17:38
Last modified: 22 Aug 2025 02:45
Export record
Altmetrics
Contributors
Author:
Hongxu Guo
Author:
Lichang Lu
Author:
Fiona L. Hatton
Author:
Lulu Xu
Author:
Eileen Yu
Author:
Ton Peijs
Author:
Emiliano Bilotti
Author:
Han Zhang
Author:
Yi Liu
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics