A fluorine-rich phenolic polyurethane elastomer with excellent self-healability and reprocessability and its applications for wearable electronics

Polyurethane elastomers with covalent adaptable networks (PU-CANs) based on the dynamic urethane bond have attracted remarkable attention owing to their reprocessability, adaptability, and self-healability. However, it is still a formidable challenge to achieve excellent dynamics at low temperatures...

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Bibliographic Details
Published in:Science China materials 2022-09, Vol.65 (9), p.2553-2564
Main Authors: Jia, Yujie, Guan, Qingbao, Zhang, Luzhi, Neisiany, Rasoul Esmaeely, Yan, Nina, Li, Ya, You, Zhengwei
Format: Article
Language:English
Subjects:
Bond energy
Chemistry and Materials Science
Chemistry/Food Science
Circuits
Conductors
Elastomers
Electronic devices
Energy harvesting
Fluorination
Fluorine
Free energy
Hydrophobicity
Low temperature
Materials Science
Mechanical properties
Nanogenerators
Open circuit voltage
Polyurethane resins
Reprocessing
Short circuit currents
Substrates
Surface energy
Surface stability
Thermal stability
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Summary:Polyurethane elastomers with covalent adaptable networks (PU-CANs) based on the dynamic urethane bond have attracted remarkable attention owing to their reprocessability, adaptability, and self-healability. However, it is still a formidable challenge to achieve excellent dynamics at low temperatures since the urethane bond energy is usually high. Herein, a fluorinated phenolic polyurethane (FPPU) elastomer with CANs based on phenol-carbamate bonds was successfully designed and prepared. Subsequently, the effects of fluorine atoms on the mechanical properties, thermal stability, reprocessability, and self-healability, surface free energy, and hydrophobicity of the prepared elastomers were systematically investigated. The FPPU elastomer showed notch-insensitivity, remarkable self-healable efficiency (98%), low dynamic dissociation temperature (60°C), excellent reprocessability, and low surface energy (62 MJ m −2 ) compared with non-fluorinated counterpart phenolic polyurethane elastomer (APPU). Based on the above-mentioned features, FPPU was selected as an elastic substrate to assemble into a triboelectric nanogenerator (TENG) to harvest energy from natural motion. This TENG exhibited an excellent electrical output performance with a peak open-circuit voltage of 103 V, a peak short-circuit current of 4.7 µA and a peak short-circuit charge of 43 nC. In addition, the TENG possessed high self-cleaning and reprocessing efficiency. Furthermore, a stretchable and self-healing composite conductor based on FPPU was fabricated for flexible electronic devices.
ISSN:2095-8226
2199-4501
DOI:10.1007/s40843-022-1985-3