Experimental Investigation on Electrical Conductivity, Dielectric Properties, and EMI Shielding Effectiveness of NiP/Graphene-Coated Natural Fiber

Electromagnetic interference (EMI) is a significant source of electromagnetic pollution that disrupts the operation of electronic devices and impacts the functioning of communication and information systems. This has necessitated the development of EMI shielding materials that are recyclable, lightw...

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Veröffentlicht in:	Journal of electronic materials 2024-02, Vol.53 (2), p.753-765
Hauptverfasser:	Mylsamy, Goudilyan, Krishnasamy, Prabu
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Sprache:	eng
Schlagworte:	Characterization and Evaluation of Materials Chemistry and Materials Science Coated fibers Dielectric properties Effectiveness Electrical resistivity Electromagnetic interference Electromagnetic shielding Electronics and Microelectronics Energy storage Frequency ranges Graphene Information systems Instrumentation Load resistance Materials Science Network analysers Optical and Electronic Materials Original Research Article Solid State Physics Superhigh frequencies
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creator	Mylsamy, Goudilyan Krishnasamy, Prabu
description	Electromagnetic interference (EMI) is a significant source of electromagnetic pollution that disrupts the operation of electronic devices and impacts the functioning of communication and information systems. This has necessitated the development of EMI shielding materials that are recyclable, lightweight, and cost-effective. Moreover, materials with high dielectric properties are in demand for energy storage applications. The present research work aims to develop an electrically conductive woven ramie fiber material through an electroless nickel–phosphorus (NiP)/graphene (Gr) coating to estimate the breaking load resistance, dielectric properties, and EMI shielding effectiveness (SE). From the obtained results, it is inferred that the electrical conductivity of the treated NiP/graphene-coated ramie fiber (T/NiP/Gr/RF) is increased by 74% (14.85 Ω cm −1 ) when compared to the T/NiP/RF fiber (8.54 Ω cm −1 ). An impedance analyzer is used to record the dielectric properties at controlled temperatures between 35°C and 60°C in the 50 Hz to 1 MHz frequency range, and the maximum dielectric constant for the NiP/Gr fiber (72.93 and 35°C) and (29.75 and 60°C). respectively, is observed at 50 Hz. The EMI SE is evaluated using a Keysight 9374A-vector network analyzer test setup at 8–12 GHz (X-band) frequency. The addition of graphene nanoparticles with the treated NiP-coated fiber increases the EMI SE T from 47.12 dB to 51 dB. The improved dielectric properties and EMI SE T of the T/NiP/Gr/RF material indicate its suitability for use in energy storage and EMI shielding applications. Graphical Abstract
doi_str_mv	10.1007/s11664-023-10811-1
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The EMI SE is evaluated using a Keysight 9374A-vector network analyzer test setup at 8–12 GHz (X-band) frequency. The addition of graphene nanoparticles with the treated NiP-coated fiber increases the EMI SE T from 47.12 dB to 51 dB. The improved dielectric properties and EMI SE T of the T/NiP/Gr/RF material indicate its suitability for use in energy storage and EMI shielding applications. 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An impedance analyzer is used to record the dielectric properties at controlled temperatures between 35°C and 60°C in the 50 Hz to 1 MHz frequency range, and the maximum dielectric constant for the NiP/Gr fiber (72.93 and 35°C) and (29.75 and 60°C). respectively, is observed at 50 Hz. The EMI SE is evaluated using a Keysight 9374A-vector network analyzer test setup at 8–12 GHz (X-band) frequency. The addition of graphene nanoparticles with the treated NiP-coated fiber increases the EMI SE T from 47.12 dB to 51 dB. The improved dielectric properties and EMI SE T of the T/NiP/Gr/RF material indicate its suitability for use in energy storage and EMI shielding applications. 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Electron. Mater</stitle><date>2024-02-01</date><risdate>2024</risdate><volume>53</volume><issue>2</issue><spage>753</spage><epage>765</epage><pages>753-765</pages><issn>0361-5235</issn><eissn>1543-186X</eissn><abstract>Electromagnetic interference (EMI) is a significant source of electromagnetic pollution that disrupts the operation of electronic devices and impacts the functioning of communication and information systems. This has necessitated the development of EMI shielding materials that are recyclable, lightweight, and cost-effective. Moreover, materials with high dielectric properties are in demand for energy storage applications. The present research work aims to develop an electrically conductive woven ramie fiber material through an electroless nickel–phosphorus (NiP)/graphene (Gr) coating to estimate the breaking load resistance, dielectric properties, and EMI shielding effectiveness (SE). From the obtained results, it is inferred that the electrical conductivity of the treated NiP/graphene-coated ramie fiber (T/NiP/Gr/RF) is increased by 74% (14.85 Ω cm −1 ) when compared to the T/NiP/RF fiber (8.54 Ω cm −1 ). An impedance analyzer is used to record the dielectric properties at controlled temperatures between 35°C and 60°C in the 50 Hz to 1 MHz frequency range, and the maximum dielectric constant for the NiP/Gr fiber (72.93 and 35°C) and (29.75 and 60°C). respectively, is observed at 50 Hz. The EMI SE is evaluated using a Keysight 9374A-vector network analyzer test setup at 8–12 GHz (X-band) frequency. The addition of graphene nanoparticles with the treated NiP-coated fiber increases the EMI SE T from 47.12 dB to 51 dB. The improved dielectric properties and EMI SE T of the T/NiP/Gr/RF material indicate its suitability for use in energy storage and EMI shielding applications. 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subjects	Characterization and Evaluation of Materials Chemistry and Materials Science Coated fibers Dielectric properties Effectiveness Electrical resistivity Electromagnetic interference Electromagnetic shielding Electronics and Microelectronics Energy storage Frequency ranges Graphene Information systems Instrumentation Load resistance Materials Science Network analysers Optical and Electronic Materials Original Research Article Solid State Physics Superhigh frequencies
title	Experimental Investigation on Electrical Conductivity, Dielectric Properties, and EMI Shielding Effectiveness of NiP/Graphene-Coated Natural Fiber
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