Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks
A highly sensitive sensor platform is significant for human–machine interactions and healthcare applications due to its instantaneous monitoring of human physiological activities. However, current flexible sensors are confronted with liability to rupture, malfunction under subzero temperatures and d...
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sg-ntu-dr.10356-1467452021-03-09T05:25:59Z Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks Ge, Gang Yuan, Wei Zhao, Wen Lu, Yao Zhang, Yizhou Wang, Wenjun Chen, Peng Huang, Wei Si, Weili Dong, Xiaochen School of Chemical and Biomedical Engineering Engineering::Chemical engineering Strain Sensor Elastomer A highly sensitive sensor platform is significant for human–machine interactions and healthcare applications due to its instantaneous monitoring of human physiological activities. However, current flexible sensors are confronted with liability to rupture, malfunction under subzero temperatures and deficient recyclability, posing great challenges to long-term implementation. Herein, a highly stretchable and healable somatosensory platform with excellent low temperature tolerance was demonstrated by adopting self-healing hydrogels as building blocks. Both metal-coordinated bonds and tetrahedral borate interactions within the binary-networked frameworks account for the satisfactory stretchability (∼550%), remarkable healed strain (∼497% after 6 h) and high healing efficiency (∼90.4%). Self-remolding capacity to regain the mechanical performance is also presented, showing superb malleability. Low temperature (−25 °C) tolerance of the sensor is favorable for all-weather applications. In addition, the piezoresistive sensor has negligible electrical hysteresis, fast response (∼31 ms) and electrically self-healable behavior. Various human motions (e.g., finger bending, phonation, and limb activity) can be differentiated by this hydrogel-based sensor. The work was supported by NNSF of China (21704043), the Natural Science Foundation of Jiangsu Province (BK20170990, 17KJB150020), Six Talent Peak Innovation Team in Jiangsu Province (TD-SWYY-009). 2021-03-09T05:25:58Z 2021-03-09T05:25:58Z 2019 Journal Article Ge, G., Yuan, W., Zhao, W., Lu, Y., Zhang, Y., Wang, W., . . . Dong, X. (2019). Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks. Journal of Materials Chemistry A, 7(11), 5949–5956. doi:/10.1039/C9TA00641A 2050-7488 https://hdl.handle.net/10356/146745 10.1039/C9TA00641A 11 7 5949 5956 en Journal of Materials Chemistry A © 2019 The Royal Society of Chemistry. All rights reserved. |
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Engineering::Chemical engineering Strain Sensor Elastomer Ge, Gang Yuan, Wei Zhao, Wen Lu, Yao Zhang, Yizhou Wang, Wenjun Chen, Peng Huang, Wei Si, Weili Dong, Xiaochen Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| description |
A highly sensitive sensor platform is significant for human–machine interactions and healthcare applications due to its instantaneous monitoring of human physiological activities. However, current flexible sensors are confronted with liability to rupture, malfunction under subzero temperatures and deficient recyclability, posing great challenges to long-term implementation. Herein, a highly stretchable and healable somatosensory platform with excellent low temperature tolerance was demonstrated by adopting self-healing hydrogels as building blocks. Both metal-coordinated bonds and tetrahedral borate interactions within the binary-networked frameworks account for the satisfactory stretchability (∼550%), remarkable healed strain (∼497% after 6 h) and high healing efficiency (∼90.4%). Self-remolding capacity to regain the mechanical performance is also presented, showing superb malleability. Low temperature (−25 °C) tolerance of the sensor is favorable for all-weather applications. In addition, the piezoresistive sensor has negligible electrical hysteresis, fast response (∼31 ms) and electrically self-healable behavior. Various human motions (e.g., finger bending, phonation, and limb activity) can be differentiated by this hydrogel-based sensor. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Ge, Gang Yuan, Wei Zhao, Wen Lu, Yao Zhang, Yizhou Wang, Wenjun Chen, Peng Huang, Wei Si, Weili Dong, Xiaochen |
| format |
Article |
| author |
Ge, Gang Yuan, Wei Zhao, Wen Lu, Yao Zhang, Yizhou Wang, Wenjun Chen, Peng Huang, Wei Si, Weili Dong, Xiaochen |
| author_sort |
Ge, Gang |
| title |
Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| title_short |
Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| title_full |
Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| title_fullStr |
Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| title_full_unstemmed |
Highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| title_sort |
highly stretchable and autonomously healable epidermal sensor based on multi-functional hydrogel frameworks |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/146745 |
| _version_ |
1695706201065521152 |