Title :
Skin and proximity effects modeling in micro-wires based on carbon nanotube bundles
Author :
Antonini, G. ; Orlandi, A. ; D´Amore, M.
Author_Institution :
Dipt. di Ing. Elettr. e dell´´Inf., Univ. degli Studi dell´´Aquila, L´´Aquila, Italy
Abstract :
Micro-wires consisting of bundles of single-wall carbon nanotubes (SWCNTs) having rectangular cross-section above a PEC ground plane are simulated in the high-frequency range. The bundles are modelled as homogeneous conductors characterized by an a.c. effective conductivity given by the Drude frequency dependent expression. The per-unit-length (p.u.l.) impedance is extracted by using the partial-element equivalent circuit (PEEC) approach. Applications to SWCNT-based micro-wires having different configurations are carried out for frequencies up to 103 GHz. Both skin and proximity effects are analysed. The computed frequency spectra of the p.u.l. effective resistance and inductance remain practically constant for frequencies above 100-200 GHz. The comparison with the high-frequency behaviour of copper micro-wires highlights the saturation effect of the SWCNTs bundles.
Keywords :
carbon nanotubes; equivalent circuits; nanowires; proximity effect (lithography); skin effect; C; Drude frequency dependent expression; PEC ground plane; SWCNT-based microwires; a.c. effective conductivity; carbon nanotube bundles; homogeneous conductors; partial-element equivalent circuit; per-unit-length impedance; proximity effect modeling; saturation effect; single-wall carbon nanotubes; skin effect; Conductivity; Conductors; Electromagnetic compatibility; Impedance; Inductance; Proximity effect; Resistance; effective impedance; nanotube bundle; signal integrity; skin and proximity effects; transmission line;
Conference_Titel :
EMC Europe 2011 York
Conference_Location :
York
Print_ISBN :
978-1-4577-1709-3
