Metamaterials absorber based on doped semiconductor for THz and FIR frequency ranges

Chen Miao; Yan Wei; Tong Xin; Zeng Liuwen; Li Zhaofeng; Yang Fuhua

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Metamaterials absorber based on doped semiconductor for THz and FIR frequency ranges

机译：基于掺杂半导体的超材料吸收器，用于THz和FIR频率范围

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In this paper, we propose a metamaterials absorber for terahertz and far infrared frequency ranges. The elementary absorber structure consists of one dielectric layer stacked on one doped semiconductor layer without structure patterning. The ideal permittivity of the doped semiconductor layer for achieving perfect absorption is derived based on the impedance transformation method. Since the permittivity of the doped semiconductor can be tuned by doping, the impedance matching condition can be met at the desired frequency range. The simulation results show that the absorption reaches 97% at the impedance matching point. Furthermore, a broadband absorber can be formed by adding one pair of patterned dielectric-doped semiconductor layers on top of the elementary absorber structure. The average absorption of the broadband absorber reaches 95% from 8 THz to 14 THz. The proposed design, which is flexible and compatible with semiconductor technology, may find its applications in fields such as terahertz detection, imaging and bioanalytics.

机译：在本文中，我们提出了一种用于太赫兹和远红外频率范围的超材料吸收器。基本吸收结构包括一个堆叠在一个掺杂的半导体层上而没有结构图案的介电层。基于阻抗变换方法导出用于实现完美吸收的掺杂半导体层的理想介电常数。由于掺杂半导体的介电常数可以通过掺杂调节，因此可以在所需的频率范围内满足阻抗匹配条件。仿真结果表明，阻抗匹配点的吸收达到97％。此外，可以通过在基本吸收器结构的顶部添加一对图案的介电掺杂的半导体层来形成宽带吸收器。宽带吸收剂的平均吸收达到8至第14至第14至第14至第14至THz。拟议的设计，灵活且与半导体技术兼容，可以在诸如太赫兹检测，成像和生物分析等领域中找到其应用。

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来源
《Journal of optics》 |2019年第3期|共6页
作者
Chen Miao; Yan Wei; Tong Xin; Zeng Liuwen; Li Zhaofeng; Yang Fuhua;
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作者单位

Chinese Acad Sci Engn Res Ctr Semicond Integrated Technol Inst Semicond Beijing 100083 Peoples R China;

Chinese Acad Sci Engn Res Ctr Semicond Integrated Technol Inst Semicond Beijing 100083 Peoples R China;

Chinese Acad Sci Engn Res Ctr Semicond Integrated Technol Inst Semicond Beijing 100083 Peoples R China;

Chinese Acad Sci Engn Res Ctr Semicond Integrated Technol Inst Semicond Beijing 100083 Peoples R China;

Chinese Acad Sci Engn Res Ctr Semicond Integrated Technol Inst Semicond Beijing 100083 Peoples R China;

Chinese Acad Sci Engn Res Ctr Semicond Integrated Technol Inst Semicond Beijing 100083 Peoples R China;

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原文格式 PDF
正文语种 eng
中图分类光学;
关键词
metamaterials; subwavelength structure; absorber;

机译：超材料;亚波长结构;吸收器;

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专利

1. Metamaterials absorber based on doped semiconductor for THz and FIR frequency ranges [J] . Chen Miao, Yan Wei, Tong Xin, Journal of optics . 2019,第3期

机译：基于掺杂半导体的超材料吸收器，用于THz和FIR频率范围
2. Theoretical design of a triple-band perfect metamaterial absorber in the THz frequency range [J] . Chunlian Cen, Zao Yi, Guangfu Zhang, Results in Physics . 2019,第1期

机译：太赫兹频率范围内三频完美超材料吸收体的理论设计
3. Ultra-broadband Polarization-Independent Wide-Angle THz Absorber Based on Plasmonic Resonances in Semiconductor Square Nut-Shaped Metamaterials [J] . Liu Xiao, Zhang Qing, Cui Xudong Plasmonics . 2017,第4期

机译：基于半导体方形螺母形状的超级谐振的超宽带极化独立角Thz吸收器
4. Liquid crystal-tunable metamaterial absorber for THz frequency range [C] . Grzeskiewicz B., Wolarz E., Sierakowski A., International Congress on Advanced Electromagnetic Materials in Microwaves and Optics . 2013

机译：用于THz频率范围的液晶可调超材料吸收器
5. EMC/FDTD/MD for multiphysics characterization of semiconductors at THz frequencies. [D] . Willis, Keely. 2010

机译：EMC / FDTD / MD用于在THz频率下对半导体进行多物理场表征。
6. An Ultra-Wideband THz/IR Metamaterial Absorber Based on Doped Silicon [O] . Huafeng Liu, Kai Luo, Shihao Tang, 2018

机译：基于掺杂硅的超宽带太赫兹/红外超材料吸收体
7. Polarization-insensitive FSS-based perfect metamaterial absorbers for GHz and THz frequencies [O] . Cumali Sabah, Furkan Dincer, Muharrem Karaaslan, 2014

机译：基于极化的FSS基于GHz和THz频率的完美超材料吸收器

Metamaterials absorber based on doped semiconductor for THz and FIR frequency ranges

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