4 research outputs found
Thermally driven self-healing using copper nanofiber heater
Nano-textured transparent heaters made of copper nanofibers (CuNFs) are used to facilitate accelerated self-healing of bromobutyl rubber (BIIR). The heater and BIIR layer are separately deposited on each side of a transparent flexible polyethylene terephthalate (PET) substrate. A pre-notched crack on the BIIR layer was bridged due to heating facilitated by CuNFs. In the corrosion test, a cracked BIIR layer covered a steel substrate. An accelerated self-healing of the crack due to the transparent copper nanofiber heater facilitated an anti-corrosion protective effect of the BIIR layer. © 2017 Author(s)
Nano-textured Copper Oxide Nanofibers for Efficient Air Cooling.
Ever decreasing of microelectronics devices is challenged by overheating and demands an increase
in heat removal rate. Herein, we fabricated highly efficient heat-removal coatings comprised of
copper oxide-plated polymer nanofiber layers (thorny devil nanofibers) with high surface-to-volume
ratio, which facilitate heat removal from the underlying hot surfaces. The electroplating time
and voltage were optimized to form fiber layers with maximal heat removal rate. The copper oxide
nanofibers with the thorny devil morphology yielded a superior cooling rate compared to the pure
copper nanofibers with the smooth surface morphology. This superior cooling performance is
attributed to the enhanced surface area of the thorny devil nanofibers. These nanofibers were characterized
with scanning electron microscopy, X-ray diffraction, atomic force microscopy, and a
thermographic camera
Silver-decorated and palladium-coated copper-electroplated fibers derived from electrospun polymer nanofibers
Here we introduce novel methods of forming silver (Ag) and palladium (Pd) fibers. The Ag and Pd fibers are fabricated by the combination of electrospinning, electroplating, and ion-exchange techniques. Their properties are characterized by scanning electron microscope with energy dispersive X-ray spectroscopy, sheet resistance meter, UV–Vis spectrophotometer, and X-ray photoelectron spectroscope. These non-woven metal fibers are free-standing and film-shaped with high electrical conductivity, as well as flexibility. Such properties are attractive for future applications of these materials in various electrochemical processes. © 2017 Elsevier B.V
Polyacrylonitrile nanofibers with added zeolitic imidazolate frameworks (ZIF-7) to enhance mechanical and thermal stability
Zeolitic imidazolate framework 7/polyacrylonitrile (ZIF-7/PAN) nanofiber mat of high porosity and surface area can be used as a flexible fibrous filtration membrane that is subjected to various modes of mechanical loading resulting in stresses and strains. Therefore, the stress-strain relation of ZIF-7/PAN nanofiber mats in the elastic and plastic regimes of deformation is of significant importance for numerous practical applications, including hydrogen storage, carbon dioxide capture, and molecular sensing. Here, we demonstrated the fabrication of ZIF-7/PAN nanofiber mats via electrospinning and report their mechanical properties measured in tensile tests covering the elastic and plastic domains. The effect of the mat fabrication temperature on the mechanical properties is elucidated. We showed the superior mechanical strength and thermal stability of the compound ZIF-7/PAN nanofiber mats in comparison with that of pure PAN nanofiber mats. Material characterization including scanning electron microscope, energy-dispersive X-ray spectroscopy, tensile tests, differential scanning calorimetry, and Fourier transform infrared spectroscopy revealed the enhanced chemical bonds of the ZIF-7/PAN complex