Ultra-Wideband RCS Reduction Achieved by a Coding Phase Gradient Metasurface

IF 3.3 4区物理与天体物理 Q2 CHEMISTRY, PHYSICAL

Plasmonics Pub Date : 2023-05-17 DOI:10.1007/s11468-023-01876-z

Bao-qin Lin, Wen-zhun Huang, Jian-xin Guo, Yan-Wen Wang, Bai-gang Huang, Rui Zhu

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Abstract

In this paper, to achieve ultra-wideband radar cross section (RCS) reduction, a coding phase gradient metasurface (CPGM) is proposed by using Pancharatnam-Berry (P-B) phase. The CPGM is composed of eight types of CPGM elements, and a series of phase gradients with different directions or starting-values will be introduced in these types of CPGM elements under the same EM-wave incidence, so it can not only achieve anomalous reflection to reduce its specular RCS but also reduce the maximum bi-static RCS due to phase cancelation. The simulation results demonstrate that the CPGM has an excellent performance in RCS reduction, compared with a pure metallic plate with the same size, its specular RCS under normal incidence with arbitrary polarization can be reduced more than 10?dB in the ultra-wide frequency band of 8.8–34.8?GHz with a relative bandwidth of 119.3%, and its maximum bi-static RCS can also be reduced effectively in the ultra-wide frequency band; moreover, when the incident angle is increased to 45°, the RCS reduction can still be achieved in an ultra-wide frequency band. Finally, an effective experimental verification is carried out.

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用编码相位梯度超表面实现超宽带RCS降频

为了实现超宽带雷达横截面(RCS)缩减，本文提出了一种利用Pancharatnam-Berry (P-B)相位的编码相位梯度超表面(CPGM)。CPGM由8种CPGM单元组成，在相同的电磁波入射下，这些CPGM单元中会引入一系列不同方向或起始值的相位梯度，因此它不仅可以实现异常反射以降低其镜面RCS，而且由于相位抵消而降低了最大双静RCS。仿真结果表明，CPGM具有优异的RCS降低性能，与相同尺寸的纯金属板相比，在任意偏振的正入射下，其镜面RCS可降低10?超宽频段8.8-34.8 ?相对带宽为119.3%，在超宽频段内也能有效降低其最大双静态RCS;此外，当入射角增加到45°时，在超宽频段内仍然可以实现RCS的降低。最后进行了有效的实验验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plasmonics 工程技术-材料科学：综合

CiteScore

5.90

自引率

6.70%

发文量

164

审稿时长

2.1 months

期刊介绍： Plasmonics is an international forum for the publication of peer-reviewed leading-edge original articles that both advance and report our knowledge base and practice of the interactions of free-metal electrons, Plasmons. Topics covered include notable advances in the theory, Physics, and applications of surface plasmons in metals, to the rapidly emerging areas of nanotechnology, biophotonics, sensing, biochemistry and medicine. Topics, including the theory, synthesis and optical properties of noble metal nanostructures, patterned surfaces or materials, continuous or grated surfaces, devices, or wires for their multifarious applications are particularly welcome. Typical applications might include but are not limited to, surface enhanced spectroscopic properties, such as Raman scattering or fluorescence, as well developments in techniques such as surface plasmon resonance and near-field scanning optical microscopy.