Tunable Transmissive Metastructure for Precise or Broadband Polarization Conversion Modulation Based on Graphene

Based on the principle of Fabry-Perot (F-P) cavity resonance and the selective permeability of gratings to specific electromagnetic waves, a graphene-based metastructure (MS) is proposed for transmissive polarization conversion (PC). Using the full-wave numerical simulation, it is found that by varying the Fermi energy of graphene, the effective resonance range of the suggested MS can be dynamically adjusted from 0.47 to 0.348-0.714 THz, achieving the target of precise to ultra-broadband polarization modulation. In this paper, the plausibility of the structure is verified from multiple perspectives, and the correlation analyses of the electric and magnetic fields are the supporting illustrations. Additionally, the triggering mechanism of PC is visually illustrated in the study of the surface currents distributions. Simulation results reveal that the MS is superior in performance, functionality, and principle, and it is foreseen to hold excellent promise for integrated equipment in the terahertz (THz) band.