Terahertz Metamaterial Modulator Based on Phase Change Material VO2

In this paper, a new type of terahertz (THz) metamaterial (MM) modulator has been presented with bifunctional properties based on vanadium dioxide (VO2). The design consists of a VO2 resonator, polyimide substrate, frequency selective surface (FSS) layer, and VO2 film. Based on the metal-insulator transition (MIT) of VO2, this structure integrated with VO2 material can achieve the dynamic modulation on both transmission and reflection waves at 2.5 THz by varying the electrical conductivity value of VO2. Meanwhile, it also exhibits adjustable absorption performance across the whole band from 0.5-7 THz. At the lower conductivity (sigma = 25 S/m), this structure can act as a bandpass FSS, and, at the high conductivity (sigma = 2 x 10(5) S/m), it behaves like a wideband absorber covering 2.52-6.06 THz with absorption A > 0.9, which realizes asymmetric transmission. The surface electric field distributions are illustrated to provide some insight into the physical mechanism of dynamic modulation. From the simulated results, it can be observed that this design has the capability of controlling tunable manipulation on both transmission/reflection responses at a wide frequency band. This proposed design may pave a novel pathway towards thermal imaging, terahertz detection, active modulators, etc.

Automated summary

A new type of THz metamaterial modulator based on VO2 has been proposed, capable of dynamic modulation at 2.5 THz and adjustable absorption performance across the band. It shows the ability to control tunable manipulation on transmission/reflection responses and has potential applications in thermal imaging, THz detection, active modulators, etc.