2023
DOI: 10.1038/s41467-023-43663-8
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Fast and scalable production of crosslinked polyimide aerogel fibers for ultrathin thermoregulating clothes

Tiantian Xue,
Chenyu Zhu,
Dingyi Yu
et al.

Abstract: Polyimide aerogel fibers hold promise for intelligent thermal management fabrics, but their scalable production faces challenges due to the sluggish gelation kinetics and the weak backbone strength. Herein, a strategy is developed for fast and scalable fabrication of crosslinked polyimide (CPI) aerogel fibers by wet-spinning and ambient pressure drying via UV-enhanced dynamic gelation strategy. This strategy enables fast sol-gel transition of photosensitive polyimide, resulting in a strongly-crosslinked gel sk… Show more

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Cited by 37 publications
(4 citation statements)
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“…Notably, the strength is much higher than previously reported aramid or its composite aerogel fibers by phase separation (0.5–8.1 MPa) , and is even comparable to aramid aerogel fibers from highly concentrated (10 wt %) aramid nanofiber liquid crystal with further drafting treatment (41 MPa) . Our HAAFs also possess superior strength to recently reported other aerogel fibers, such as polyimide aerogel fibers (2.1–22 MPa), ,,, cellulose aerogel fibers (5.8–30.0 MPa), and core–shell structured chitosan-TPU aerogel fibers (12.7 MPa) . Noteworthily, our HAAF-5 achieves a large elongation at break of 99.1% with a C s of 4 wt %, which surpasses all previously reported aramid aerogel fibers (10–40%). The comparison of the strength, elongation, and thermal conductivity properties with other aerogel fibers in Figure S8.The calculated toughness is as high as 23.14 MJ/m 3 , rivaling that of high-toughness cellulose aerogel fibers in a very recent work .…”
Section: Resultsmentioning
confidence: 82%
“…Notably, the strength is much higher than previously reported aramid or its composite aerogel fibers by phase separation (0.5–8.1 MPa) , and is even comparable to aramid aerogel fibers from highly concentrated (10 wt %) aramid nanofiber liquid crystal with further drafting treatment (41 MPa) . Our HAAFs also possess superior strength to recently reported other aerogel fibers, such as polyimide aerogel fibers (2.1–22 MPa), ,,, cellulose aerogel fibers (5.8–30.0 MPa), and core–shell structured chitosan-TPU aerogel fibers (12.7 MPa) . Noteworthily, our HAAF-5 achieves a large elongation at break of 99.1% with a C s of 4 wt %, which surpasses all previously reported aramid aerogel fibers (10–40%). The comparison of the strength, elongation, and thermal conductivity properties with other aerogel fibers in Figure S8.The calculated toughness is as high as 23.14 MJ/m 3 , rivaling that of high-toughness cellulose aerogel fibers in a very recent work .…”
Section: Resultsmentioning
confidence: 82%
“…Skin-attachable electronics need accessibility to heat dissipation to maintain thermal comfort on the human skin [ 56 , 57 ]. As illustrated in Fig.…”
Section: Resultsmentioning
confidence: 99%
“…The thermal conductivity of PAI aerogel fiber fabrics was significantly better than those of most reported LPF-PAF (40.1 mW/(m·K)), PI-AF (28.7 ± 2.0 mW/(m·K)), ANF/CNT-AF (42–60 mW/(m·K)), and PI/Ti 3 C 2 T x -AF (36 mW/(m·K)) fabrics. The intuitive comparison to illustrate the superior thermal conductivity of the PAI/PU@340 fabric is given in Figure d, and the detailed information about thermal conductivity could be found in Table S5. ,,,, …”
Section: Resultsmentioning
confidence: 99%