THz properties of grating-gate plasmonic crystals crystals

IF 0.3 4区 物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY Lithuanian Journal of Physics Pub Date : 2023-12-15 DOI:10.3952/physics.2023.63.4.7
P. Sai, M. Dub, V. Korotyeyev, S. Kukhtaruk, G. Cywiński, W. Knap
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Abstract

This study reviews recent advances in the modern field of terahertz plasmonics concerning the control of resonant properties of grating-gate plasmonic crystal structures. Particularly, we conducted both experimental and theoretical investigations of AlGaN/GaN grating-gate structures with a focus on investigations of the resonant structure of transmission spectra associated with plasmon excitations in two-dimensional electron gas at different modulation degree of concentration profiles. Two distinct resonant phases of the plasmonic crystal structure were analyzed. The first one, the delocalized phase, is observed in the case of a small modulation degree of electron gas. In this phase, we found that plasmonic resonant absorption of incident radiation occurs across the entire grating-gate structure, with domination in the gated regions of the electron gas. In contrast, the second phase, the localized one, is realized at a strong modulation of the electron concentration profiles when the gated regions of the electron gas are completely depleted. Here, plasmon resonances are characterized by the spatial localization of absorption of incident radiation exclusively within the ungated regions of the electron gas. Moreover, in the localized phase, we observed the unexpected blue shift of plasmon resonant frequency with an increase of gate voltage. This observation was explained by the result of ‘edge gating effect’ and additional shrinking of the concentration profile of the electron gas in the ungated region. We demonstrate that the correct description of both phases requires rigorous electrodynamic simulations and cannot be achieved solely in the frameworks of simplified single-mode or single-cavity models.
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光栅栅极等离子晶体晶体的太赫兹特性
本研究回顾了现代太赫兹等离子体学领域有关控制光栅栅极等离子体晶体结构共振特性的最新进展。特别是,我们对氮化铝/氮化镓栅极结构进行了实验和理论研究,重点研究了二维电子气中等离子激元在不同调制度浓度剖面下的透射光谱共振结构。研究分析了质子晶体结构的两个不同共振阶段。第一种是在电子气体调制度较小的情况下观察到的脱局域阶段。在这一阶段,我们发现入射辐射的等离子体共振吸收发生在整个光栅-栅极结构中,电子气体的栅极区域占主导地位。相比之下,第二阶段,即局部阶段,是在电子气体的门控区域完全耗尽时,在电子浓度曲线的强烈调制下实现的。在这种情况下,等离子体共振的特点是入射辐射的吸收完全在电子气的非门控区域内进行空间定位。此外,在本地化阶段,我们观察到等离子体共振频率会随着栅极电压的增加而发生意想不到的蓝移。这一观察结果可以用 "边缘门控效应 "和非门控区域电子气体浓度曲线的额外收缩来解释。我们证明,要正确描述这两个阶段,需要进行严格的电动力学模拟,而不能仅在简化的单模或单腔模型框架内实现。
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来源期刊
Lithuanian Journal of Physics
Lithuanian Journal of Physics 物理-物理:综合
CiteScore
0.90
自引率
16.70%
发文量
21
审稿时长
>12 weeks
期刊介绍: The main aim of the Lithuanian Journal of Physics is to reflect the most recent advances in various fields of theoretical, experimental, and applied physics, including: mathematical and computational physics; subatomic physics; atoms and molecules; chemical physics; electrodynamics and wave processes; nonlinear and coherent optics; spectroscopy.
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