Ambient-conditions spinning of functional soft fibers via engineering molecular chain networks and phase separation

Zhang, Songlin; Zhou, Mengjuan; Liu, Mingyang; Guo, Zi Hao; Qu, Hao; Chen, Wenshuai; Tan, Swee Ching

Ambient-conditions spinning of functional soft fibers via engineering molecular chain networks and phase separation

Songlin Zhang, Mengjuan Zhou, Mingyang Liu, Zi Hao Guo, Hao Qu, Wenshuai Chen () and Swee Ching Tan ()
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Songlin Zhang: National University of Singapore
Mengjuan Zhou: National University of Singapore
Mingyang Liu: National University of Singapore
Zi Hao Guo: National University of Singapore
Hao Qu: National University of Singapore
Wenshuai Chen: Northeast Forestry University
Swee Ching Tan: National University of Singapore

Nature Communications, 2023, vol. 14, issue 1, 1-12

Abstract: Abstract Producing functional soft fibers via existing spinning methods is environmentally and economically costly due to the complexity of spinning equipment, involvement of copious solvents, intensive consumption of energy, and multi-step pre-/post-spinning treatments. We report a nonsolvent vapor-induced phase separation spinning approach under ambient conditions, which resembles the native spider silk fibrillation. It is enabled by the optimal rheological properties of dopes via engineering silver-coordinated molecular chain interactions and autonomous phase transition due to the nonsolvent vapor-induced phase separation effect. Fiber fibrillation under ambient conditions using a polyacrylonitrile-silver ion dope is demonstrated, along with detailed elucidations on tuning dope spinnability through rheological analysis. The obtained fibers are mechanically soft, stretchable, and electrically conductive, benefiting from elastic molecular chain networks via silver-based coordination complexes and in-situ reduced silver nanoparticles. Particularly, these fibers can be configured as wearable electronics for self-sensing and self-powering applications. Our ambient-conditions spinning approach provides a platform to create functional soft fibers with unified mechanical and electrical properties at a two-to-three order of magnitude less energy cost under ambient conditions.

Date: 2023
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DOI: 10.1038/s41467-023-38269-z

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