Polarization multiplexing multichannel high-Q terahertz sensing system

IF 4.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Frontiers in Nanotechnology Pub Date : 2023-02-08 DOI:10.3389/fnano.2023.1112346
Xiuyu Wang, Xiaoman Wang, Q. Ren, Haocheng Cai, J. Xin, Yuxin Lang, Xiaofei Xiao, Z. Lan, J. You, W. E. Sha
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引用次数: 1

Abstract

Terahertz functional devices with high-Q factor play an important role in spectral sensing, security imaging, and wireless communication. The reported terahertz devices based on the electromagnetic induction transparency (EIT) effect cannot meet the needs of high-Q in practical applications due to the low-Q factor. Therefore, to increase the Q-factor of resonance, researchers introduced the concept of bound state in the continuum (BIC). In the quasi-BIC state, the metasurface can be excited by the incident wave and provide resonance with a high-Q factor because the condition that the resonant state of the BIC state is orthogonal is not satisfied. The split ring resonator (SRR) is one of the most representative artificial microstructures in the metasurface field, and it shows great potential in BIC. In this paper, based on the classical single-SRR array structure, we combine the large and small SRR and change the resonance mode of the inner and outer SRR by changing the outer radius of the inner SRR. The metasurface based on parameter-tuned BIC verified that the continuous modulation of parameters in a system could make a pair of resonant states strongly coupled, and the coherent cancellation of the resonant states will cause the linewidth of one of the resonant states to disappear, thus forming BIC. Compared with the single-SRR array metasurface based on symmetry-protected BIC, the dual-SRR array metasurface designed in this paper has multiple accidental BICs and realizes multichannel multiplexing of X-polarization and Y-polarization. It provides a brilliant platform for high-sensitivity optical sensor array, low threshold laser and efficient optical harmonic generation.
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偏振复用多通道高q太赫兹传感系统
具有高Q因子的太赫兹功能器件在光谱传感、安全成像和无线通信中发挥着重要作用。已报道的基于电磁感应透明(EIT)效应的太赫兹器件由于低Q因子而无法满足实际应用中对高Q的需求。因此,为了增加共振的Q因子,研究人员引入了连续体中束缚态(BIC)的概念。在准BIC状态下,元表面可以被入射波激发,并提供具有高Q因子的谐振,因为不满足BIC状态的谐振状态正交的条件。开口环谐振器(SRR)是超表面领域最具代表性的人工微结构之一,在BIC中显示出巨大的潜力。本文在经典的单SRR阵列结构的基础上,将大SRR和小SRR相结合,通过改变内SRR的外半径来改变内外SRR的谐振模式。基于参数调谐BIC的元表面验证了系统中参数的连续调制可以使一对谐振态强耦合,谐振态的相干消除将导致其中一个谐振态的线宽消失,从而形成BIC。与基于对称保护BIC的单SRR阵列元表面相比,本文设计的双SRR阵列元表面具有多个偶然BIC,实现了X偏振和Y偏振的多路复用。它为高灵敏度光学传感器阵列、低阈值激光器和高效的光学谐波产生提供了一个出色的平台。
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来源期刊
Frontiers in Nanotechnology
Frontiers in Nanotechnology Engineering-Electrical and Electronic Engineering
CiteScore
7.10
自引率
0.00%
发文量
96
审稿时长
13 weeks
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