Propagation of electromagnetic waves in anisotropic nanostructural materials based on 3D lattices of oriented carbon nanotubes with magnetic nanoparticles in the microwave band

Abstract

Mathematical modeling of propagation of electromagnetic waves in 3D periodic lattices of oriented carbon nanotubes (CNs) with magnetic nanoparticles in the millimeter wave band is performed. Real and imaginary parts of complex propagation coefficients of longitudinal (counterclockwise polarized and clockwise polarized) waves and transverse (ordinary and extraordinary) waves (the zero spatial harmonic) propagating in a 3D lattice of oriented CNs with magnetic nanoparticles are calculated at frequency f = 26 GHz as functions of the intensity and direction of the external magnetostatic field for different numbers of magnetic nanoparticles taken into account in an elementary cell (an autonomous block with virtual Floquet channels) of the model.