Fabrication of Polymer Nanofiber-Conducting Polymer Fabric and Noncontact Motion Sensing Platform
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BRONZE
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Yes
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Abstract
Conductive polymer-electrospun polymer nanofiber network was combined to host iron oxide nanoparticles providing micrometer thick sensing interface. The sensor has fabricated as freestanding fabric exhibiting 10 to 100 KOhm base resistivity upon bias applied. The moving object has been sensed through the electrostatic interactions between fibers and object. The sensing range has been found to be 1-5 cm above the surface of fabric. By the controlled combination of conductive polymers electrospun polymer nanofibers effective device miniaturization has been provided without loss of performance. The noncontact motion sensor platform has unique flexibility and light weight holding a potential for wearable sensor technology.
Description
10th Japanese-Mediterranean Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting, Multifunctional and Nano Materials, JAPMED’10 2017; Izmir; Turkey; 4 July 2017 through 8 July 2017
Keywords
Contactless sensing, Electrospunned nanofibers, Dielectric properties, Carbon nanotube, PEDOT:PSS, PSS [PEDOT], Electrospunned nanofibers, Dielectric properties, Contactless sensing, Carbon nanotube
Fields of Science
02 engineering and technology, 0210 nano-technology, 01 natural sciences, 0104 chemical sciences
Citation
Mutlu, M. U., Akın, O., Demir, M. M., and Yıldız, Ü. H. (2018). Fabrication of polymer nanofiber-conducting polymer fabric and noncontact motion sensing platform. In A.G. Mamalis, M. Enokizono, A.Kladas, T. Sawada, M. Güden and M. M. Demir (Eds.), Materials Science Forum: Applied Electromagnetic Engineering for Advanced Materials from Macro-to Nanoscale under Static-to Shock Loading, (pp. 207-212). Switzerland: Trans Tech Publications. doi:10.4028/www.scientific.net/MSF.915.207
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915
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Start Page
207
End Page
212
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