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Investigation and configuration of an absorber with tunability across terahertz broadband relying upon graphene proportional architecture

Xinrui Huang, Jun Zhu, Zao Yi, Shubo Cheng, Boxun Li, Yougen Yi

2026Modern Physics Letters B23 citationsDOI

Abstract

In response to the problems such as complex structure, poor tunability and limited working bandwidth existing in current terahertz broadband absorbers, this study designs a tunable terahertz absorber based on the proportionally arranged graphene. This device adopts a simple three-layer structure. By optimizing the size ratio of each resonant region of the surface graphene, it achieves a broadband and highly efficient absorption of over 90% in the frequency range 2.69–5.92[Formula: see text]THz, with an average absorption rate of 97.3%. It also has good impedance matching characteristics and angle adaptability. The research shows that the broadband absorption property of this device stems from the electric field coupling effect between different resonant units. This coupling effect enables multiple absorption peaks to overlap and broaden the bandwidth. Moreover, by applying an external voltage to regulate the Fermi level of graphene, the absorption bandwidth can be continuously adjusted. The device demonstrates flexible dynamic control capabilities and has good tolerance to the incident angle of electromagnetic waves. This study provides a feasible solution for designing a simple-structured and tunable high-efficiency terahertz absorber. This design has potential application value in the fields of terahertz detection, communication, and stealth technology.

Topics & Concepts

Terahertz radiationMaterials scienceBroadbandBandwidth (computing)OptoelectronicsImpedance matchingAbsorption (acoustics)GrapheneElectrical impedanceElectric fieldCoupling (piping)MicrowaveVoltageMetamaterial absorberOpticsWidebandElectromagnetic fieldPolarization (electrochemistry)CloakingElectromagnetic radiationSpecific absorption rateCenter frequencyResonatorFermi levelDipoleHeterojunctionMetamaterials and Metasurfaces ApplicationsPlasmonic and Surface Plasmon ResearchElectromagnetic wave absorption materials