Miniaturized and Actively Tunable Triple-Band Terahertz Metamaterial Absorber Using an Analogy I-Typed Resonator

• Published in: Nanoscale research letters Vol. 17; no. 1; pp. 35 - 12
• Main Authors: Wang, Ben-Xin, Xu, Chongyang, Duan, Guiyuan, Jiang, Jieying, Xu, Wei, Yang, Zhuchuang, Wu, Yangkuan
• Format: Journal Article
• Language: English
• Published: New York Springer US 15.03.2022; Springer Nature B.V; SpringerOpen
• Subjects: Absorbers; Absorbers (materials); Absorption; Analogy I-typed resonator; Chemistry and Materials Science; Materials Science; Metamaterials; Miniaturization; Modulation; Molecular Medicine; Nanochemistry; Nanoscale Science and Technology; Nanotechnology; Nanotechnology and Microengineering; Notches; Optimization; Perfect absorber; Phase transitions; Resonators; Terahertz frequencies; Terahertz metamaterial; Triple-band absorption; Unit cell; Vanadium; Vanadium dioxide; Analogy I-typed resonator; Perfect absorber; Triple-band absorption; Terahertz metamaterial
• ISSN: 1556-276X; 1931-7573; 1556-276X
• DOI: 10.1186/s11671-022-03677-5

Triple-band terahertz metamaterial absorber with design of miniaturization and compactness is presented in this work. The unit cell of the terahertz absorber is formed by an analogy I-typed resonator (a rectangular patch with two small notches) deposited on top of dielectric sheet and metallic mirror. The miniaturized structure design exhibits three discrete frequency points with near-perfect absorption at terahertz regime. The three absorption peaks could be ascribed to localized resonances of analogy I-typed resonator, while the response positions of these absorption peaks at the analogy I-typed resonator are different by analyzing the near-field patterns of these resonance peaks. Changes in structure parameters of the analogy I-typed resonator are also investigated. Simulation results revealed that the notch sizes of the rectangular patch are the key factor to form the triple-band near-perfect absorption. Further structure optimization is given to demonstrate triple-band polarization insensitive performance. Moreover, actively tunable absorption properties are realized by inserting or introducing vanadium dioxide with adjustable conductivity into the metamaterial structure. It is revealed that the insulator–metal phase transition of vanadium dioxide is the main reason for the modulation of absorption performance. Compared with previous multiple-band absorbers, the device given here has excellent features of high degrees of simplification, miniaturization, and active modulation, these are important in practical applications.