Tunable terahertz Dirac semimetal metamaterials

The tunable propagation properties of 3D Dirac semimetal (DSM) patterned metamaterial (MM) structures have been symmetrically investigated in the terahertz (THz) regime. The results demonstrate that the resonant properties are very sensitive to the thicknesses of DSM MMs, and hundreds of nanometers are required to excite strong resonant curves. The DSM MMs support both strong LC and dipolar resonances, quite different from graphene MM patterns which mainly depend on dipolar resonance. As the Fermi level increases, the resonant strength becomes stronger, and significant modulation can be achieved, e.g. the amplitude and frequency modulation depths of transmission curves are more than 99% and 80%, respectively. In addition, by utilizing asymmetrical resonators, a very sharp Fano resonant peak is achieved with a large Q-factor of more than 25, for which the figure of merit is about 20. The results are very helpful to understand the tunable mechanisms of DSM devices and design novel THz plasmonic components, such as modulators, filters, and sensors.

Automated summary

The tunable propagation properties of 3D Dirac semimetal patterned metamaterial structures in the terahertz regime have been symmetrically investigated. The results show that resonant properties are highly sensitive to the thicknesses of DSM MMs and support strong LC and dipolar resonances. By increasing the Fermi level, resonant strength becomes stronger, and asymmetrical resonators can achieve a very sharp Fano resonant peak with a large Q-factor.