Abstract :
In this paper, we report the design, analysis, and simulation of a novel quadrupleband metamaterial absorber at microwave frequencies. The absorber is composed of delicate periodic patterned structures and a metallic background plane, which are separated by a dielectric substrate. By manipulating the periodic patterned structures, nearly perfect absorption can be obtained at four specific resonance frequencies. Moreover, the significantly high absorptions of quadruple peaks are insensitive to polarization independence, and the influence of the incident angle on the absorption for both TE and TM modes was also analyzed. To explain the absorption mechanism of the suggested structures, the electric and magnetic field distributions and the resistance matching principle were given. Importantly, the design idea has the ability to be extended to other frequencies, such as terahertz, infrared, and optical frequencies.
Keywords :
light absorption; microwave metamaterials; microwave photonics; optical design techniques; optical metamaterials; TE modes; TM modes; absorber design; delicate periodic patterned structures; dielectric substrate; electric field distribution; incident angle effect; magnetic field distribution; metallic background plane; nearly perfect absorption; polarization independence; quadruple-band microwave metamaterial absorber; resistance matching; resonance frequencies; Absorption; Dielectric substrates; Electric fields; Impedance; Magnetic fields; Metamaterials; Resonant frequency; Absorber; Metamaterials; Subwavelength structures; absorber; subwavelength structures;
