Login / Signup

Multifunctional Electrically Conductive Copper Electroplated Fabrics Sensitizes by In-Situ Deposition of Copper and Silver Nanoparticles.

Azam AliFiaz HussainAmbreen KalsoomTauqeer RiazMuhammad Zaman KhanZakariya ZubairKhubab ShakerJiri MilitkyMuhammad Tayyab NomanMunir Ashraf
Published in: Nanomaterials (Basel, Switzerland) (2021)
In this study, we developed multifunctional and durable textile sensors. The fabrics were coated with metal in two steps. At first, pretreatment of fabric was performed, and then copper and silver particles were coated by the chemical reduction method. Hence, the absorbance/adherence of metal was confirmed by the deposition of particles on microfibers. The particles filled the micro spaces between the fibers and made the continuous network to facilitate the electrical conduction. Secondly, further electroplating of the metal was performed to make the compact layer on the particle- coated fabric. The fabrics were analyzed against electrical resistivity and electromagnetic shielding over the frequency range of 200 MHz to 1500 MHz. The presence of metal coating was confirmed from the surface microstructure of coated fabric samples examined by scanning electron microscopy, EDS, and XRD tests. For optimized plating parameters, the minimum surface resistivity of 67 Ω, EMI shielding of 66 dB and Ohmic heating of 118 °C at 10 V was observed. It was found that EMI SH was increased with an increase in the deposition rate of the metal. Furthermore, towards the end, the durability of conductive textiles was observed against severe washing. It was observed that even after severe washing there was an insignificant increase in electrical resistivity and good retention of the metal coating, as was also proven with SEM images.
Keyphrases
  • silver nanoparticles
  • electron microscopy
  • drug delivery
  • early onset
  • gold nanoparticles
  • oxidative stress
  • skeletal muscle
  • insulin resistance
  • mass spectrometry
  • oxide nanoparticles
  • network analysis