Details

Autor(en) / Beteiligte

• Wang, Sai
• Ding, Ruida
• Liang, Guoqiang
• Zhang, Wei
• Yang, Fengjin
• Tian, Yucheng
• Yu, Jianyong
• Zhang, Shichao
• Ding, Bin

Titel

Direct Synthesis of Polyimide Curly Nanofibrous Aerogels for High‐Performance Thermal Insulation Under Extreme Temperature

Ist Teil von

• Advanced materials (Weinheim), 2024-03, Vol.36 (13), p.e2313444-n/a

Ort / Verlag

Germany: Wiley Subscription Services, Inc

Erscheinungsjahr

2024

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Maintaining human body temperature is one of the basic needs for living, which requires high‐performance thermal insulation materials to prevent heat exchange with external environment. However, the most widely used fibrous thermal insulation materials always suffer from the heavy weight, weak mechanical property, and moderate capacity to suppress heat transfer, resulting in limited personal cold and thermal protection performance. Here, an ultralight, mechanically robust, and thermally insulating polyimide (PI) aerogel is directly synthesized via constructing 3D interlocked curly nanofibrous networks during electrospinning. Controlling the solution/water molecule interaction enables the rapid phase inversion of charged jets, while the multiple jets are ejected by regulating charge density of the fluids, thus synergistically allowing numerous curly nanofibers to interlock and cross‐link with each other to form porous aerogel structure. The resulted PI aerogel integrates the ultralight property with density of 2.4 mg cm−3, extreme temperature tolerance (mechanical robustness over −196 to 300 °C), and thermal insulation performance with ultralow thermal conductivity of 22.4 mW m−1 K−1, providing an ideal candidate to keep human thermal comfort under extreme temperature. This work can provide a source of inspiration for the design and development of nanofibrous aerogels for various applications. A polyimide (PI) nanofibrous aerogel consisted of interlocked curly nanofibrous networks (crimp percentage 28.5%) is directly assembled by electrospinning. Benefiting from strong porous aerogel structure (porosity 99.8%), the PI aerogel achieves ultralight property (density 2.4 mg cm−3), mechanical robustness at extreme conditions, and ultralow thermal conductivity (22.4 mW m−1 K−1), thereby offering a promising candidate for thermal insulation under extreme temperature.