4.7 Article

Flexible Electromagnetic Shielding Nano-Composites Based on Silicon and NiFe2O4 Powders

Journal

POLYMERS
Volume 15, Issue 11, Pages -

Publisher

MDPI
DOI: 10.3390/polym15112447

Keywords

flexible electromagnetic shielding; silicon composites with NiFe2O4 nano-powders; dielectric characteristics; electromagnetic shielding effectiveness; thermal stability; lifetime

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This paper presents the obtaining and characterization of five experimental models of novel polymer composite materials with ferrite nano-powder. The composites were obtained by mechanically mixing two components and pressing the obtained mixture on a hot plate press. The purpose of this work was to obtain a flexible composite material, applicable to any type of architecture for the electrical and automotive industry, necessary for protection against electromagnetic interference. The results demonstrated the efficiency of such materials at lower frequencies, but also in the microwave domain, with higher thermal stability and lifetime.
In this paper, the obtaining and characterization of five experimental models of novel polymer composite materials with ferrite nano-powder are presented. The composites were obtained by mechanically mixing two components and pressing the obtained mixture on a hot plate press. The ferrite powders were obtained by an innovative economic co-precipitation route. The characterization of these composites consisted of physical and thermal properties: hydrostatic density, scanning electron microscopy (SEM), and TG DSC thermal analyses, along with functional electromagnetic tests in order to demonstrate the functionality of these materials as electromagnetic shields (magnetic permeability, dielectric characteristics, and shielding effectiveness). The purpose of this work was to obtain a flexible composite material, applicable to any type of architecture for the electrical and automotive industry, necessary for protection against electromagnetic interference. The results demonstrated the efficiency of such materials at lower frequencies, but also in the microwave domain, with higher thermal stability and lifetime.

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