Polymer Composites for Flexible Electromagnetic Shields

Harmful electromagnetic (EM) interference (EMI) to living beings and various sensitive instruments by EM radiations from electronic and electrical gadgets and mobile towers is increasing rapidly. It inflicts illness, and presumably cancerous growth in human cells. EMI is minimized by wrapping the re...

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Bibliographic Details
Published in:Macromolecular symposia. 2018-10, Vol.381 (1), p.n/a
Main Authors: Sahu, Kriti R., De, Udayan
Format: Article
Language:English
Subjects:
Barium titanates
Cadmium
Cloth
composites
Conducting polymers
Electromagnetic shielding
Electronic devices
Emitters
Emitters (electron)
Ferroelectric materials
Ferroelectricity
Frequencies
Lead niobates
Measuring instruments
metal‐polymer complexes
Network analysers
oxides
Polymer matrix composites
polymeric electromagnetic shields
Polymers
Radar Absorbing Materials
silicones
Workshops
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Summary:Harmful electromagnetic (EM) interference (EMI) to living beings and various sensitive instruments by EM radiations from electronic and electrical gadgets and mobile towers is increasing rapidly. It inflicts illness, and presumably cancerous growth in human cells. EMI is minimized by wrapping the receiver and/or the emitter gaplessly by an efficient EM shielding sheet. Compared to the widely used and classical metallic shields, 2nd generation polymer composite EMI shields are lighter and more flexible. Conventional polymer composites use conducting polymers and metallic/carbon powders that have conducting electrons to reflect EM waves away. A polymeric binder, curing overnight to a soft and flexible sheet, has presently been selected for making the polymeric composites. We test EM shielding by certain non‐metallic composites. We review results for composites with fine metallic fibers (copper and brass turnings, available as waste from mechanical workshops) or conducting forms of cadmium oxide or ferroelectric materials (PbNb2O6 [o‐PN] & BaTiO3 [BT]) or their mixtures (52 samples). Small pieces of these cloth‐like polymeric sheets have been characterized in a Vector Network Analyzer (VNA), by measuring input power (Pin), the reflected power (Prefl), and the transmitted power (Pout), over five frequency bands in 700 MHz to 40 GHz range to find Shielding Effectiveness (SE) = 10 log (Pout/Pin) and Reflection Effectiveness = 10 log (Prefl/Pin). Success of o‐PN, BT, conducting (fired) Cd‐O, metallic turnings and their combinations has been discussed, highlighting some new observations. Composites, developed in this work, include EMI Shielding materials and potential Radar Absorption Materials.
ISSN:1022-1360
1521-3900
DOI:10.1002/masy.201800097