Liu Shuxiang, Li Shufang
Beijing Key Laboratory of Network System Architecture and Convergence, Beijing University of Posts and Telecommunications, Beijing 100876, China.
Materials (Basel). 2021 Oct 26;14(21):6427. doi: 10.3390/ma14216427.
In this paper, we theoretically designed and numerically analyzed an ultrabroadband meta-absorber with near unity absorptivity that works in terahertz spectrum. A wideband meta-absorber composed of bilayer patterned graphene and dielectric cylinder array with high symmetry was proposed. The wideband absorption mechanism benefited from two aspects. The first one was enhanced surface plasmons based on bilayer patterned graphene. And the second one was the coupling of continuous resonant modes within Fabry-Perot cavities to the enhanced surface plasmons in the graphene. An ultrawide bandwidth with absorptivity over 90% were obtained from 3.2 THz to 9.4 THz. Simulated results showed that the proposed ultra-wideband absorbing structure also possessed high performance of polarization independence, flexible tunability, large incident angle insensitivity, and compact fabrication.
在本文中,我们从理论上设计并数值分析了一种在太赫兹光谱范围内具有近单位吸收率的超宽带超材料吸收体。提出了一种由具有高对称性的双层图案化石墨烯和介质圆柱阵列组成的宽带超材料吸收体。宽带吸收机制得益于两个方面。第一个方面是基于双层图案化石墨烯增强的表面等离子体激元。第二个方面是法布里 - 珀罗腔内连续共振模式与石墨烯中增强的表面等离子体激元的耦合。在3.2太赫兹至9.4太赫兹范围内获得了吸收率超过90%的超宽带。模拟结果表明,所提出的超宽带吸收结构还具有偏振无关、灵活可调、对大入射角不敏感以及易于紧凑制造等高性能。