Design and optimization of hexagonal tungsten ring metasurface perfect absorbers with circuit model

IF 1.6 4区化学 Q4 CHEMISTRY, PHYSICAL

Surface and Interface Analysis Pub Date : 2024-08-05 DOI:10.1002/sia.7346

Ali Reza Sarikhani, Mohammad Reza Salehi, Seyedeh Leila Mortazavifar, Mojtaba Shahraki, Ebrahim Abiri

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引用次数: 0

Abstract

In this paper, a perfect absorber (PA) based on tungsten is proposed to include hexagonal‐shaped metasurface absorbers with varying hole sizes ranging from quadrangular to circular, allowing them to cover a wide wavelength spectrum. The study investigates the effects of various parameters, including the number of sides of the inner hole, on the absorber's performance and identifies the most suitable absorber by introducing an equivalent circuit. The outcomes of full‐wave numerical simulations primarily based on the finite element method (FEM) highly correspond to the final results of the circuit model. Additionally, the circuit model significantly reduces computation time and requires less storage compared with full‐wave simulations. The results show that the hexagonal‐square metasurface absorber achieves exceptional absorption rates, with an average of 99.9% in the 431 to 532 nm wavelength range and over 90% in the 300 to 915 nm range. The hexagonal‐hexagonal metasurface absorber also exhibits high absorption rates, with an average of over 99% in the 431 to 518 nm and 700 to 780 nm ranges, and over 90% in the 300 to 940 nm range. The absorption performance of the proposed hexagonal‐circle metasurface absorber is also remarkable, with an absorption value of over 99% in the 670 to 771 nm range and above 90% in the 365 to 991 nm range. These models can be utilized to design and simulate other subwavelength absorbers in a broad frequency range, including terahertz and visible light, making them suitable for various applications.

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利用电路模型设计和优化六边形钨环元表面完美吸收器

本文提出了一种基于钨的完美吸收器 (PA)，包括六角形元面吸收器，其孔的大小从四角形到圆形不等，使其能够覆盖很宽的波长谱。研究调查了包括内孔边数在内的各种参数对吸收器性能的影响，并通过引入等效电路确定了最合适的吸收器。主要基于有限元法（FEM）的全波数值模拟结果与电路模型的最终结果高度吻合。此外，与全波模拟相比，电路模型大大缩短了计算时间，所需的存储空间也更小。结果表明，六角形-方形元表面吸收器的吸收率非常高，在 431 至 532 纳米波长范围内平均吸收率为 99.9%，在 300 至 915 纳米波长范围内平均吸收率超过 90%。六角形-六角形元表面吸收器也表现出很高的吸收率，在 431 至 518 纳米和 700 至 780 纳米波长范围内平均吸收率超过 99%，在 300 至 940 纳米波长范围内平均吸收率超过 90%。拟议的六角形圆元表面吸收器的吸收性能也非常显著，在 670 至 771 纳米范围内的吸收值超过 99%，在 365 至 991 纳米范围内的吸收值超过 90%。这些模型可用于设计和模拟包括太赫兹和可见光在内的宽频率范围内的其他亚波长吸收器，使其适用于各种应用。

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

Surface and Interface Analysis 化学-物理化学

CiteScore

3.30

自引率

5.90%

发文量

130

审稿时长

4.4 months

期刊介绍： Surface and Interface Analysis is devoted to the publication of papers dealing with the development and application of techniques for the characterization of surfaces, interfaces and thin films. Papers dealing with standardization and quantification are particularly welcome, and also those which deal with the application of these techniques to industrial problems. Papers dealing with the purely theoretical aspects of the technique will also be considered. Review articles will be published; prior consultation with one of the Editors is advised in these cases. Papers must clearly be of scientific value in the field and will be submitted to two independent referees. Contributions must be in English and must not have been published elsewhere, and authors must agree not to communicate the same material for publication to any other journal. Authors are invited to submit their papers for publication to John Watts (UK only), Jose Sanz (Rest of Europe), John T. Grant (all non-European countries, except Japan) or R. Shimizu (Japan only).