利用非对称石墨烯金属表面实现高性能太赫兹相干完美吸收

IF 2.1 4区物理与天体物理 Q2 OPTICS

Photonics Pub Date : 2024-06-07 DOI:10.3390/photonics11060544

Jintao Chen, Lujun Hong, Jiangtao Lei, Yun Shen, Xiaohua Deng, Jing Chen, Tianjing Guo

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引用次数: 0

摘要

在这项工作中，我们介绍了一种新型相干完美吸收器，通过强调其宽带宽、厚度减小、可调特性以及通过使用非对称石墨烯元表面实现的简单设计，突出了它的新颖性。这种设计将方形和圆形石墨烯贴片排列在硅衬底的两侧。通过优化结构设计，这种吸收器能在 1.65 至 4.49 太赫兹的频率范围内持续捕获 90% 以上的入射波，石墨烯费米级为 0.8 eV，而整个器件的厚度仅为 1.5 um。这使得我们的吸收器比以前的设计更加有效和紧凑。通过将元表面的几何设计与石墨烯费米水平相结合，吸收器的效能将得到显著提高。预计这种超薄、宽带相干完美吸收器件将在新兴片上太赫兹通信技术（包括光调制器、光电探测器等）中发挥关键作用。

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High-Performance Terahertz Coherent Perfect Absorption with Asymmetric Graphene Metasurface

In this work, we introduce a novel coherent perfect absorber, accentuating its novelty by emphasizing the broad bandwidth, reduced thickness, tunable property, and straightforward design achieved through the use of an asymmetric graphene metasurface. This design incorporates both square and circular graphene patches arranged on either side of a silicon substrate. With an optimized structural design, this absorber consistently captures over 90% of incoming waves across the frequency range of 1.65 to 4.49 THz, with a graphene Fermi level of 0.8 eV, and the whole device measures just 1.5 um thick. This makes our absorber significantly more effective and compact than previous designs. The absorber’s effectiveness can be significantly enhanced by combining the metasurface’s geometric design with the graphene Fermi level. It is anticipated that this ultrathin, wideband coherent perfect absorption device will play a crucial role in emerging on-chip THz communication technologies, including light modulators, photodetectors, and so on.

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来源期刊

Photonics Physics and Astronomy-Instrumentation

CiteScore

2.60

自引率

20.80%

发文量

817

审稿时长

8 weeks

期刊介绍： Photonics (ISSN 2304-6732) aims at a fast turn around time for peer-reviewing manuscripts and producing accepted articles. The online-only and open access nature of the journal will allow for a speedy and wide circulation of your research as well as review articles. We aim at establishing Photonics as a leading venue for publishing high impact fundamental research but also applications of optics and photonics. The journal particularly welcomes both theoretical (simulation) and experimental research. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Electronic files and software regarding the full details of the calculation and experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material.