Flexible Sensor Based on Fe 3 O 4 ‐COOH@Ti 3 C 2 T x MXene Rapid‐Gelating Hydrogel for Human Motion Monitoring

Abstract Although hydrogels are still in their infancy, research is primarily focused on optimizing their mechanical, antibacterial, anti‐frost, and water‐retaining properties. However, the rapid preparation of hydrogels without external energy stimulation remains a significant challenge. In this st...

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Published inAdvanced materials interfaces Vol. 9; no. 22
Main Authors Hu, Yongqin, Hou, Chen, Du, Jihe, Fan, Qianxi, Fang, Junan, Shi, Yuxia, Yang, Guanghao, An, Jia, Liu, Yufei
Format Journal Article
LanguageEnglish
Published 01.08.2022
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Abstract Abstract Although hydrogels are still in their infancy, research is primarily focused on optimizing their mechanical, antibacterial, anti‐frost, and water‐retaining properties. However, the rapid preparation of hydrogels without external energy stimulation remains a significant challenge. In this study, a Fe 3 O 4 ‐COOH@MXene@silk fibroin@polyacrylamide hybrid hydrogel (FM@SF‐PAAM) is successfully fabricated using an innovative rapid gelation method, which can initiate the gelation process as low as 7 s and formed at an extremely rapid rate at room temperature, without the use of external energy. The as‐obtained FM@SF‐PAAM hybrid hydrogel exhibits excellent electrical conductivity (6.44 × 10 –2  S m –1 ) and mechanical properties, with a maximum strain of 1660%. Additionally, the FM@SF‐PAAM‐based flexible strain sensor can monitor joint movement and emotional changes, such as finger and elbow bending, glaring, smiling, and mouth opening. Thus, the radical polymerization process demonstrates the immense potential for application to nearly all types of MXene‐based hydrogels and is likely to serve as a foundation for the development of flexible hydrogel‐based devices.
AbstractList Abstract Although hydrogels are still in their infancy, research is primarily focused on optimizing their mechanical, antibacterial, anti‐frost, and water‐retaining properties. However, the rapid preparation of hydrogels without external energy stimulation remains a significant challenge. In this study, a Fe 3 O 4 ‐COOH@MXene@silk fibroin@polyacrylamide hybrid hydrogel (FM@SF‐PAAM) is successfully fabricated using an innovative rapid gelation method, which can initiate the gelation process as low as 7 s and formed at an extremely rapid rate at room temperature, without the use of external energy. The as‐obtained FM@SF‐PAAM hybrid hydrogel exhibits excellent electrical conductivity (6.44 × 10 –2  S m –1 ) and mechanical properties, with a maximum strain of 1660%. Additionally, the FM@SF‐PAAM‐based flexible strain sensor can monitor joint movement and emotional changes, such as finger and elbow bending, glaring, smiling, and mouth opening. Thus, the radical polymerization process demonstrates the immense potential for application to nearly all types of MXene‐based hydrogels and is likely to serve as a foundation for the development of flexible hydrogel‐based devices.
Author Fan, Qianxi
Liu, Yufei
Hou, Chen
An, Jia
Du, Jihe
Hu, Yongqin
Yang, Guanghao
Fang, Junan
Shi, Yuxia
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crossref_primary_10_1021_acsami_3c14210
crossref_primary_10_1002_mame_202200519
crossref_primary_10_1016_j_jcis_2023_12_039
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