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Ink-jet printing of particle-free silver inks on fabrics with a superhydrophobic protection layer for fabrication of robust electrochemical sensors

A brief representation of the fabric-based sensor fabrication process. [Display omitted] •Flexible sensors were constructed by inkjet printing of particle-free silver inks.•A novel superhydrophobic coating was applied to enhance the stability of sensors.•Flexible sensors have an excellent resilience...

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Bibliographic Details
Published in:Microchemical journal 2021-05, Vol.164, p.106038, Article 106038
Main Authors: Ipekci, Hasan Huseyin, Gozutok, Zehra, Celik, Nusret, Serdar Onses, M., Uzunoglu, Aytekin
Format: Article
Language:English
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Summary:A brief representation of the fabric-based sensor fabrication process. [Display omitted] •Flexible sensors were constructed by inkjet printing of particle-free silver inks.•A novel superhydrophobic coating was applied to enhance the stability of sensors.•Flexible sensors have an excellent resilience against bending.•Fabric-based flexible sensors displayed high sensitivity in a wide linear range. The present work demonstrates the fabrication of novel flexible sensors by the deposition of conductive silver patterns on polyester-based fabrics. The conductive layer on the textile surface was formed by ink-jet printing of particle-free silver inks and a subsequent heat treatment. A novel approach is presented to define the working area and ensure high electrode stability by deposition of a superhydrophobic coating on the conductive patterns. The physical and chemical characterizations of the fabricated electrodes were conducted using X-ray diffraction (XRD), scanning electron microscopy (SEM), energy dispersive spectroscopy (EDX), and contact angle measurements. The conductivity of the printed electrodes was highly stable against repeated bending cycles. Hydrogen peroxide was used as the model analyte to evaluate the electrochemical sensing performance of the textile-based flexible sensors. The chronoamperometry results indicated a high sensitivity of 295.3 ± 0.04 µA mM−1 cm−2 (n = 5) with the linear range of 50 µM-70 mM. The results suggested that our novel textile-based electrode design is an excellent candidate for the construction of flexible electrochemical sensors with high conductivity and catalytic activity, high bending resilience, wide sensing window, and excellent storage stability.
ISSN:0026-265X
1095-9149
DOI:10.1016/j.microc.2021.106038