Abstract

In this work, we take advantage of the characteristic of bulk Dirac semimetals (BDS) that their Fermi level can be controlled by electrostatic doping, as well as the phase transition characteristics of vanadium dioxide (VO 2 ). Combining these two materials, we designed a terahertz metamaterial absorber with multiple control methods. It has four absorption peaks in the range of 1.5 THz to 6 THz, and the absorption rates are all above 95 %, reaching a maximum of 99.8 %. When the Fermi level of Dirac semimetals rises from 80 to 100 meV, the resonance frequency of four absorption bands of our equipment goes up, and the absorption rate remains stable, some even magnifying. The absorption peak with the largest increase in amplitude changed from 92.4 % to 99.9 %, an increase of 7.5 %. The maximum regulation range of the absorption peaks is as high as 0.34 THz. In addition, we explained the absorption principle of the equipment from two aspects: relative impedance matching and analysis of the electric field intensity distribution map, and we demonstrated the rationality of our absorber structure design through parameter scanning. Our absorber also has excellent polarization insensitivity and high refractive index sensitivity. It has potential application value in sensing, detection, medical and other fields, and our design provides new reference value for absorber designs with multiple regulation methods. Our absorber has four absorption peaks in the range of 1.5–6 THZ, and the absorption rates are all above 95 %, reaching a maximum of 99.8 %. When the Fermi level of Dirac semimetals increases from 80 mev to 100 mev, the resonance frequency of the absorption bands of ourl equipment up and the absorption rate remains stable, some even magnifying. The absorption peak which with the largest increase in amplitude, change from 92.4 % to 99.9 %, an increase of 7.5 %. The maximum regulation range of the absorption peaks is as high as 0.34 THZ. In addition, our equipment also has good polarization stability. The assignment of proving our absorption principle has been fulfilled by us using the relative impedance theory. To the structural parameters of the absorber, and the change of environmental sensitivity, we qualitative research respectively. The refractive index sensitivity (S) has been calculated and analyzed, which reflects the stability when it working of our absorber. Our work puts forward a new scheme for exploration of outstanding switch and the fusion of different metamaterials. • The absorber has four absorption peaks in the range of 1.5–6 THZ, and the absorption rates are all above 95 %, reaching a maximum of 99.8 %. • The absorber has two methods of regulation, namely controlling the Fermi level of BDS, and promoting the phase transition of VO 2 . • The absorber has High refractive index sensitivity and excellent polarization stability.