Graphene-based metamaterial ultrawideband absorber with enhanced terahertz performance
Abbas Movahednia, Valiollah Mashayekhi, Ehsan Zareian‐Jahromi, Seyed Mohamad Hashemi
Abstract
• Ultrawideband absorption: Achieves above 90% absorption across a 14.55 THz bandwidth in the terahertz regime. • Water-enhanced absorption: Broadens bandwidth up to 14.55 THz by integrating water between graphene layers. • Polarization insensitivity: Maintains stable absorption for both TE and TM polarizations under normal incidence. • Angle stability: Stable absorption for TM up to 60° and TE up to 55° (except between 5-8 THz). • Advanced metamaterial design: Dual-layer graphene and water encapsulation provide robust ultrawideband absorption. In this paper, we present a graphene-based metamaterial ultrawideband absorber operating in the terahertz regime. The absorber is composed of two patterned and continuous graphene layers, a bottom gold layer, and a SiO 2 substrate that separates the continuous graphene layer from the gold layer. The absorption spectrum is enhanced by integrating a graphene resonator with water, which has frequency-dependent permittivity. The water is encapsulated in polytetrafluoroethylene (PTFE) in the form of a circular ring sandwiched between the two graphene layers. Simulation results show that the absorber attains a 90 % absorption bandwidth of about 14.55 THz. The proposed absorber is polarization-insensitive under normal incidence. For TE polarization, the absorption level remains stable for incident angles θ from 0° to 55° across the entire frequency band (14.55 THz), except for the 5–8 THz range. For TM polarization, the absorption level remains stable for θ ranging from 0° to 60° over the entire bandwidth. Additionally, the absorption level is consistent for both TM and TE polarizations across the entire bandwidth for incident angles φ from 0° to 90°.