Dynamic tunable multiple plasmon induced transparency sensor and optical switch in dual-polarization excitation in a terahertz graphene metamaterial

This paper proposes the development of a simplified graphene-based terahertz device that exhibits multiple plasmon induced transparency (PIT) effects in x-polarized and y-polarized waves. The PIT device is composed of "Z-shaped" and "parallel strips" structures, which demonstrate multiple transparency windows under x-polarized and y-polarized incident light within the frequency range of 2-15 THz. Additionally, under x-polarized incident, the device demonstrates wideband transparency at 3.4 THz. By comparing the transmission spectra of individual and combined structures, we observe that the initial transmission valley of the single two horizontal stripes structure transforms into a PIT curve in the combined structure, while the transmission valley of the other individual structures remains transmission. The PIT device demonstrates a peak sensitivity of 3THz/RIU for x-polarized waves and 2.9THz/RIU for y-polarized waves when employed as a light sensor. PIT as a light switch can attain a maximum modulation depth of 81.4% for x-polarized waves and 71.2% for y-polarized waves at Fermi energy levels ranging from 0.5eV to 1.2eV. The presented PIT device shows promise for applications in high-sensitivity optical sensing and optical switching.