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基于超材料吸收体的全向偏振探测器

An Omnidirectional Polarization Detector Based on a Metamaterial Absorber.

作者信息

Zhang Binzhen, Zhang Yong, Duan Junping, Zhang Wendong, Wang Wanjun

机构信息

Science and Technology on Electronic Test & Measurement Laboratory, North University of China, Taiyuan 030051, China.

School of Instrument and Electronics, North University of China, Taiyuan 030051, China.

出版信息

Sensors (Basel). 2016 Jul 23;16(8):1153. doi: 10.3390/s16081153.

DOI:10.3390/s16081153
PMID:27455280
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5017319/
Abstract

The theory, design, simulation, fabrication, and performance of an omnidirectional polarization detector (PD) with two resonances located in the X and Ka ranges based on a metamaterial absorber (MMA) are presented in this paper. The sandwich structure of PD is composed of 0.1 μm periodic "I" shaped patches on the metasurface, a dielectric of 200 μm FR-4 on the interlayer, and a 0.3 μm copper film on the substrate. PD absorptivity is first used to reflect and describe the polarization of the incident wave. The numerical results, derived from the standard full wave finite integration technology (FIT) of CST 2015, indicates that the designed PD shows polarization sensitivity at all incidence angles. The effects on absorptivity produced by the incidence angles, polarization angles, and materials are investigated. The amplitude of absorptivity change caused by polarization reaches 99.802%. A laser ablation process is adopted to prepare the designed PD on a FR-4 board coated with copper on the double plane with a thickness that was 1/93 and 1/48 of wavelength at a resonance frequency of 16.055 GHz and 30.9 GHz, respectively. The sample test results verify the designed PD excellent detectability on the polarization of the incident waves. The proposed PD, which greatly enriches the applications of metamaterials in bolometers, thermal images, stealth materials, microstructure measurements, and electromagnetic devices, is easy to mass produce and market because of its strong detectability, ultrathin thickness, effective cost, and convenient process.

摘要

本文介绍了一种基于超材料吸收体(MMA)的全向偏振探测器(PD)的理论、设计、模拟、制造及性能,该探测器在X波段和Ka波段有两个共振频率。PD的三明治结构由超表面上0.1μm周期的“I”形贴片、中间层200μm厚的FR-4电介质以及衬底上0.3μm厚的铜膜组成。首先利用PD的吸收率来反射和描述入射波的偏振。通过CST 2015的标准全波有限积分技术(FIT)得到的数值结果表明,所设计的PD在所有入射角下均表现出偏振敏感性。研究了入射角、偏振角和材料对吸收率的影响。偏振引起的吸收率变化幅度达到99.802%。采用激光烧蚀工艺在双面镀铜的FR-4板上制备所设计的PD,其厚度分别为16.055GHz和30.9GHz共振频率下波长的1/93和1/48。样品测试结果验证了所设计的PD对入射波偏振具有优异的探测能力。所提出的PD由于其强大的探测能力、超薄的厚度、有效的成本和便捷的工艺,极大地丰富了超材料在测辐射热计、热成像、隐身材料、微观结构测量和电磁器件中的应用,易于大规模生产和推向市场。

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