Versatile terahertz metasurface: dynamic switching between electromagnetically induced transparency and perfect absorption

Abstract

This paper introduces a versatile metasurface based on vanadium dioxide (VO2) and graphene that seamlessly transitions between electromagnetically induced transparency (EIT) and multi-band absorption through VO2’s phase change property. When VO2 is in a dielectric state, the device can generate EIT. This configuration allows dynamic tuning of the central frequency by adjusting the graphene’s Fermi levels (E f ), achieving a remarkable group delay of 1.42 ps. When VO2 is in a metallic state, the structure facilitates a Fabry–Perot resonance between the VO2 layer at the bottom and the graphene layer at the top, leading to exceptional light absorption. Specifically, absorptivity of 99.8% and 99.4% is achieved at 1.66 THz and 2.87 THz, respectively. In addition, these two resonance peaks can also be dynamically adjusted by modulating E f . Furthermore, the device serves as a highly sensitive sensor with sensitivity up to 0.65 THz/RIU. Notably, both absorption and EIT modes are polarization-insensitive and exhibit tolerance to a wide range of incidence angles. Consequently, the proposed device holds significant promise across various applications within the electromagnetic field, including tunable devices, absorbers, sensors, slow-light devices, and so on.