Title :
Waves in anisotropic metamaterials comprised of finite L-C meshes
Author :
Brennan, E.P. ; Gardiner, A. ; Schuchinsky, A.G. ; Fusco, V.F.
Author_Institution :
Belfast Queens Univ., Ireland
Abstract :
2D periodic lattices and finite grids of lumped L-C elements have been investigated to elucidate the mechanisms governing wave phenomena in this kind of metamaterial. Isofrequencies for a lattice unit cell and circuit simulations of finite meshes have shown that such a medium exhibits unusual properties of channeling power from a point source into pencil beams which can propagate only along specific trajectories. The beam direction varies with frequency, and at the resonance frequency ω = 1/(LC)12 /, the phase and group velocities of the transmitted wave are orthogonal. It is shown that the channeled beams do not obey the laws of geometrical optics (Snell´s law, Brewster angle, etc.) at the skewed interfaces of dissimilar meshes, and that beam scattering is governed by the local conditions of the phase synchronization and impedance matching. Finally a new physical planar L-C mesh unit cell arrangement has been designed and measured.
Keywords :
anisotropic media; electromagnetic wave propagation; electromagnetic wave scattering; equivalent circuits; impedance matching; mesh generation; metamaterials; periodic structures; synchronisation; 2D periodic lattices; RLC mesh; anisotropic metamaterials; backward waves; beam scattering; finite L-C meshes; group velocity; impedance matching; lattice unit cell isofrequency; lumped L-C elements; negative refraction; pencil beam propagation; phase synchronization; phase velocity; planar L-C mesh unit cell; resonance cones; Anisotropic magnetoresistance; Circuit simulation; Frequency synchronization; Geometrical optics; Impedance matching; Lattices; Metamaterials; Optical scattering; Resonance; Resonant frequency;
Conference_Titel :
Microwave Symposium Digest, 2005 IEEE MTT-S International
Print_ISBN :
0-7803-8845-3
DOI :
10.1109/MWSYM.2005.1517060
