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Superhydrophobic, Highly Conductive, and Trilayered Fabric with Connected Carbon Nanotubes for Energy-Efficient Electrical Heating.

Xi YuJinlin YeCanjian LiYue YuHuiting YangLingrui WenJinfu HuangWanhao XuYeer WuQiang ZhouZijin LiuBingyan LiLihuan WangHui YuJianhua YanXianfeng Wang
Published in: ACS applied materials & interfaces (2024)
Current electrically heated fabrics provide heat in cold climates, suffer from abundant wasted radiant heat energy to the external environment, and are prone to damage by water. Thus, constructing energy-efficient and superhydrophobic conductive fabrics is in high demand. Therefore, we propose an effective and facile methodology to prepare a superhydrophobic, highly conductive, and trilayered fabric with a connected carbon nanotube (CNT) layer and a titanium dioxide (TiO 2 ) nanoparticle heat-reflecting layer. We construct polyamide/fluorinated polyurethane (PA/FPU) nanofibrous membranes via first electrospinning, then performing blade-coating with the polyurethane (PU) solution with CNTs, and finally fabricating FPU/TiO 2 nanoparticles via electrospraying. This strategy causes CNTs to be connected to form a conductive layer and enables TiO 2 nanoparticles to be bound together to form a porous, heat-reflecting layer. As a consequence, the as-prepared membranes demonstrate high conductivity with an electrical conductivity of 63 S/m, exhibit rapid electric-heating capacity, and exhibit energy-efficient asymmetrical heating behavior, i.e., the heating temperature of the PA/FPU nanofibrous layer reaches more than 83 °C within 90 s at 24 V, while the heating temperature of the FPU/TiO 2 layer only reaches 53 °C, as well as prominent superhydrophobicity with a water contact angle of 156°, indicating promising utility for the next generation of electrical heating textiles.
Keyphrases
  • carbon nanotubes
  • tissue engineering
  • quantum dots
  • reduced graphene oxide
  • heat stress
  • visible light
  • oxidative stress
  • mass spectrometry
  • sensitive detection