带宽可调谐的太赫兹超构材料半波片器件

吕婷婷; 付天舒; 刘东明; 史金辉

doi:10.37188/CO.2022-0198

带宽可调谐的太赫兹超构材料半波片器件

1.
东北石油大学物理与电子工程学院, 黑龙江大庆 163318
2.
哈尔滨工程大学物理与光电工程学院, 纤维集成光学教育部重点实验室, 黑龙江哈尔滨150001

详细信息

中图分类号: TP394.1; TH691.9
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- 文章访问数: 320
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- 被引次数: 0
出版历程
- 收稿日期: 2022-09-24
- 修回日期: 2022-11-02
- 网络出版日期: 2022-12-09

Bandwidth-tunable terahertz metamaterial half-wave plate component

doi: 10.37188/CO.2022-0198

1.
School of Physics and Electronic Engineering, Northeast Petroleum University, Daqing 163318, China
2.
Key Laboratory of In-Fiber Integrated Optics of Ministry of Education, College of Physics and Optoelectronic Engineering, Harbin Engineering University, Harbin 150001, China

Funds: Supported by National Natural Science Foundation of China (No. U1931121)

More Information

Author Bio:
LV Ting-ting (1989—), female, Tangyuan city, Heilongjiang province, lecturer, received her PhD degree from School of Physics and Optoelectronic Engineering, Harbin Engineering University in 2022. She is mainly engaged in the research of structural design and application of tunable metamaterials. E-mail: oktingting521@126.com

SHI Jin-hui (1979—), male, Zhaodong city, Heilongjiang province, professor and doctoral supervisor, received his PhD degree in materials science from Harbin Engineering University in 2007. He is mainly engaged in the application research of metamaterials. E-mail: shijinhui@hrbeu.edu.cn

Corresponding author: oktingting521@126.com; shijinhui@hrbeu.edu.cn

摘要

摘要:
基于二氧化钒（vanadium dioxide, VO₂）的相变原理，提出了一种“树叶型”复合超构材料，能够实现带宽可调谐的半波片功能。VO₂薄膜为绝缘态时，复合超构材料可以看作是空芯“树叶型”金属结构，能够实现双频带的半波片功能。在1.01~1.17 THz和1.47~1.95 THz 频带范围内能够将y偏振光转换成x偏振光，偏振转换率大于0.9且平均相对带宽为26%。VO₂ 薄膜为金属态时，实芯“树叶型”金属结构的超构材料在1.13~2.80 THz范围内能够实现反射型的宽频带半波片功能，相对带宽为85%。利用瞬时表面电流分布和电场理论详细地分析了带宽可调谐半波片器件的工作原理。本文所提出的“树叶型”复合超构材料半波片器件在太赫兹成像、传感和偏振探测等领域具有潜在的应用前景。
- 超构材料 /
- 半波片 /
- 带宽可调谐 /
- 太赫兹 /
- VO₂
Abstract:
We propose a “leaf-type” hybrid metamaterial to realize bandwidth-tunable half-wave plate based on vanadium dioxide (VO₂) phase transition. The hybrid metamaterial is regarded as a hollow “leaf-type” metallic structure and act as a dual-band half-wave plate when VO₂ film is in the insulating phase. Within 1.01−1.17 THz and 1.47−1.95 THz, it can accomplish y- to x-polarization conversion with a polarization conversion rate over 0.9 and an average relative bandwidth of 26%. The metamaterial becomes a solid core “leaf-type” metallic structure when VO₂ is in the metallic phase. Within 1.13−2.80 THz, it can act as a broadband half-wave plate with a relative bandwidth of 85%. The working principle of the bandwidth-tunable half-wave plate is explained by the instantaneous surface current distribution and electric field theory in detail. The proposed “leaf-type” hybrid metamaterial half-wave plate has potential application prospects in THz imaging, sensing and polarization detection.
- metamaterial /
- half-wave plate /
- bandwidth-tunable /
- terahertz /
- VO₂

HTML全文

图 1 “树叶型”复合超构材料的工作原理和结构示意图。（a）半波片工作原理图（偏振旋转角φ和倾斜入射角θ已在插图中标注）；（b）基本单元的结构参数图

Figure 1. Operation principle of “leaf-type” hybrid metamaterial and it’s structural diagram. (a) Schematic diagram of half-wave plate (The polarization angle φ and incident angle θ are marked in the inset); (b) structural parameters of a unit cell in the proposed metamaterial

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图 2 VO₂薄膜为不同相态时“树叶型”复合超构材料的反射偏振特性。（a）和（b）共偏振和正交偏振反射系数；（c）和（d）偏振转换率

Figure 2. Reflection polarization properties of “leaf-type” hybrid metamaterial when the VO₂ film is in different phase states. (a) and (b) Reflection coefficients of co- and cross-polarization; (c) and (d) Polarization Conversion Ratio (PCR)

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图 3 y偏振光激发下6个特定频率处的偏振椭圆

Figure 3. Polarization ellipses of reflected lights at the six specific frequencies under y-polarized illumination.

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图 4 VO₂薄膜为不同相态时，垂直入射的u偏振和v偏振激发“树叶型”复合超构材料的反射系数和相位频谱图。（a）和（b）反射系数r_uu，r_vv和r_uv，r_vu；（c）和（d）φ_uu和φ_vv及其相位差Δφ（u偏振和v偏振如插图所示）

Figure 4. Reflection coefficients and phases of the hybrid metamaterial for normal u and v polarization incidences when the VO₂ film is in different phase states. (a) and (b) Reflection coefficients r_uu, r_vvand r_uv, r_vu; (c) and (d) reflection phases φ_uu, φ_vvand phase difference Δφ (normal u and v polarization incidences, as depicted by the inset)

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图 5 关键频率处的瞬时表面电流分布图。VO₂为绝缘态时，（a）1.22 THz、（b）1.68 THz、（c）2.10 THz、（d）2.61 THz；VO₂为金属态时，（e）1.22 THz、（f）1.95 THz、（g）2.10 THz、（h）2.71 THz

Figure 5. Instantaneous surface current distributions at critical frequencies. (a) 1.22 THz, (b) 1.68 THz, (c) 2.10 THz, (d) 2.61 THz for VO₂ film in the complete insulating state; (e) 1.22 THz, (f) 1.95 THz, (g) 2.10 THz, (h) 2.71 THz for VO₂ film in the complete metallic state

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图 6 VO₂薄膜为绝缘态和金属态时，带宽可调谐半波片器件随入射角度θ的变化规律。（a）和（b）r_xy；（c）和（d）PCR

Figure 6. Incident angle dependence of bandwidth-tunable half-wave plate components when VO₂ film is in the complete insulating and metallic states. (a) and (b) r_xy; (c) and (d) PCR

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图 7 VO₂薄膜为绝缘态和金属态时带宽可调谐半波片器件随偏振角度的变化规律。（a）和（b）r_xy；（c）和（d）PCR

Figure 7. Polarization angle dependence of bandwidth-tunable half-wave plate components when VO₂ film is in the complete insulating and metallic states. (a) and (b) r_xy; (c) and (d) PCR

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