Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials
Encapsulation of polyamines for the practical application of self-healing epoxy is promising yet challenging due to their high reactivity and good solubility in water and most organic solvents. Herein, we developed an innovative method to directly synthesize microcapsules containing pure polyamine b...
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sg-ntu-dr.10356-1393832020-05-19T05:59:45Z Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials Zhang, He Zhang, Xin Bao, Chenlu Li, Xin Sun, Dawei Duan, Fei Friedrich, Klaus Yang, Jinglei School of Civil and Environmental Engineering School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Polymerization Self-healing Materials Encapsulation of polyamines for the practical application of self-healing epoxy is promising yet challenging due to their high reactivity and good solubility in water and most organic solvents. Herein, we developed an innovative method to directly synthesize microcapsules containing pure polyamine by integrating microfluidic emulsion and interfacial polymerization. Using this integration to make full use of the advantages and avoid the shortcomings of the involved two techniques, the properties of the fabricated microcapsules could be delicately tailored according to the practical demands of self-healing materials. The superiority of the obtained polyamine microcapsules was demonstrated via a dual-microcapsule high-performance self-healing system with fully autonomous recoverability, high thermal and long-term stability, relatively fast healing kinetics. The highest healing efficiency of 111 ± 12% in terms of recovered mode I fracture toughness was achieved at room temperature for 48 h without any external intervention. The high performance, environmental stability, and low cost and toxicity introduced by the robust microcapsules promote the potential practical application of this self-healing system. 2020-05-19T05:59:45Z 2020-05-19T05:59:45Z 2018 Journal Article Zhang, H., Zhang, X., Bao, C., Li, X., Sun, D., Fei, D., . . . Yang, J. (2018). Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials. Journal of Materials Chemistry A, 6(47), 24092-24099. doi:10.1039/C8TA08324J 2050-7488 https://hdl.handle.net/10356/139383 10.1039/C8TA08324J 47 6 24092 24099 en Journal of Materials Chemistry A © 2018 The Royal Society of Chemistry. All rights reserved. |
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Engineering::Mechanical engineering Polymerization Self-healing Materials Zhang, He Zhang, Xin Bao, Chenlu Li, Xin Sun, Dawei Duan, Fei Friedrich, Klaus Yang, Jinglei Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| description |
Encapsulation of polyamines for the practical application of self-healing epoxy is promising yet challenging due to their high reactivity and good solubility in water and most organic solvents. Herein, we developed an innovative method to directly synthesize microcapsules containing pure polyamine by integrating microfluidic emulsion and interfacial polymerization. Using this integration to make full use of the advantages and avoid the shortcomings of the involved two techniques, the properties of the fabricated microcapsules could be delicately tailored according to the practical demands of self-healing materials. The superiority of the obtained polyamine microcapsules was demonstrated via a dual-microcapsule high-performance self-healing system with fully autonomous recoverability, high thermal and long-term stability, relatively fast healing kinetics. The highest healing efficiency of 111 ± 12% in terms of recovered mode I fracture toughness was achieved at room temperature for 48 h without any external intervention. The high performance, environmental stability, and low cost and toxicity introduced by the robust microcapsules promote the potential practical application of this self-healing system. |
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School of Civil and Environmental Engineering |
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School of Civil and Environmental Engineering Zhang, He Zhang, Xin Bao, Chenlu Li, Xin Sun, Dawei Duan, Fei Friedrich, Klaus Yang, Jinglei |
| format |
Article |
| author |
Zhang, He Zhang, Xin Bao, Chenlu Li, Xin Sun, Dawei Duan, Fei Friedrich, Klaus Yang, Jinglei |
| author_sort |
Zhang, He |
| title |
Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| title_short |
Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| title_full |
Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| title_fullStr |
Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| title_full_unstemmed |
Direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| title_sort |
direct microencapsulation of pure polyamine by integrating microfluidic emulsion and interfacial polymerization for practical self-healing materials |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/139383 |
| _version_ |
1681058472919040000 |