The use of novel nanocomposites, consisting in polymeric-based system filled with graphite-nanoplatelets (GNP), is proposed to increase the shielding performance and to reduce the Q of small enclosures excited by impinging plane waves in the gigahertz frequency range. Structure and electrical characteristics of the realized GNP-based composites are described. Absorbing performances of a planar infinite screen made with two layers panel backed on a metallic surface, illuminated by a TM and a TE polarized plane waves, are computed in reverberating conditions. The same absorbing nanostructure is considered to realize the walls of a small-dimensions cubic box with a slot aperture. The full-wave numerical simulations demonstrate that the use of the new material produces resonance damping of microwave electric field and a factor 10 4 reduction of the Q of a full-metallic enclosure. © 2012 IEEE.
Graphite nano-platelet-based composites for microwave absorbing small enclosures / D'Aloia, ALESSANDRO GIUSEPPE; Tamburrano, Alessio; D'Amore, Marcello; Sarto, Maria Sabrina. - STAMPA. - (2012), pp. 629-632. (Intervento presentato al convegno 2012 Asia-Pacific Symposium on Electromagnetic Compatibility, APEMC 2012 tenutosi a Singapore nel 21 May 2012 through 24 May 2012) [10.1109/apemc.2012.6237917].
Graphite nano-platelet-based composites for microwave absorbing small enclosures
D'ALOIA, ALESSANDRO GIUSEPPE;TAMBURRANO, Alessio;D'AMORE, Marcello;SARTO, Maria Sabrina
2012
Abstract
The use of novel nanocomposites, consisting in polymeric-based system filled with graphite-nanoplatelets (GNP), is proposed to increase the shielding performance and to reduce the Q of small enclosures excited by impinging plane waves in the gigahertz frequency range. Structure and electrical characteristics of the realized GNP-based composites are described. Absorbing performances of a planar infinite screen made with two layers panel backed on a metallic surface, illuminated by a TM and a TE polarized plane waves, are computed in reverberating conditions. The same absorbing nanostructure is considered to realize the walls of a small-dimensions cubic box with a slot aperture. The full-wave numerical simulations demonstrate that the use of the new material produces resonance damping of microwave electric field and a factor 10 4 reduction of the Q of a full-metallic enclosure. © 2012 IEEE.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
