THz plasmonics and electronics in germanene nanostrips

IF 4.8 4区 物理与天体物理 Q2 PHYSICS, CONDENSED MATTER
Talia Tene, Marco Guevara, Gabriela Tubon-Usca, Oswaldo Villacrés Cáceres, Gabriel Moreano, Cristian Vacacela Gomez, Stefano Bellucci
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引用次数: 1

Abstract

Abstract Germanene nanostrips (GeNSs) have garnered significant attention in modern semiconductor technology due to their exceptional physical characteristics, positioning them as promising candidates for a wide range of applications. GeNSs exhibit a two-dimensional (buckled) honeycomb-like lattice, which is similar to germanene but with controllable bandgaps. The modeling of GeNSs is essential for developing appropriate synthesis methods as it enables understanding and controlling the growth process of these systems. Indeed, one can adjust the strip width, which in turn can tune the bandgap and plasmonic response of the material to meet specific device requirements. In this study, the objective is to investigate the electronic behavior and THz plasmon features of GeNSs (≥100 nm wide). A semi-analytical model based on the charge-carrier velocity of freestanding germanene is utilized for this purpose. The charge-carrier velocity of freestanding germanene is determined through the GW approximation ( m·s −1 ). Within the width range of 100 to 500 nm, GeNSs exhibit narrow bandgaps, typically measuring only a few meV. Specifically, upon analysis, it was found that the bandgaps of the investigated GeNSs ranged between 29 and 6 meV. As well, these nanostrips exhibit -like plasmon dispersions, with their connected plasmonic frequency (≤30 THz) capable of being manipulated by varying parameters such as strip width, excitation plasmon angle, and sample quality. These manipulations can lead to frequency variations, either increasing or decreasing, as well as shifts towards larger momentum values. The outcomes of our study serve as a foundational motivation for future experiments, and further confirmation is needed to validate the reported results.
锗纳米带的太赫兹等离子体和电子学
锗烯纳米带(GeNSs)由于其特殊的物理特性在现代半导体技术中引起了极大的关注,使其成为广泛应用的有前途的候选者。gns表现出二维(屈曲)蜂窝状晶格,与锗烯相似,但具有可控的带隙。GeNSs的建模对于开发适当的合成方法至关重要,因为它可以理解和控制这些系统的生长过程。事实上,人们可以调整条带宽度,这反过来可以调整带隙和等离子体响应的材料,以满足特定的器件要求。在本研究中,目的是研究GeNSs(≥100 nm宽)的电子行为和太赫兹等离子体特征。本文采用了基于独立锗烯载流子速度的半解析模型。通过GW近似(m·s−1)确定了独立锗烯的载流子速度。在100到500纳米的宽度范围内,GeNSs的带隙很窄,通常只有几个meV。具体来说,经过分析,发现所研究的GeNSs的带隙范围在29 - 6 meV之间。此外,这些纳米条带表现出类似等离子体色散的特性,其连接的等离子体频率(≤30太赫兹)可以通过不同的参数(如条带宽度、激发等离子体角度和样品质量)来控制。这些操作可能导致频率变化,增加或减少,以及向更大的动量值转移。我们的研究结果作为未来实验的基础动机,需要进一步的确认来验证报告的结果。
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
Journal of Semiconductors
Journal of Semiconductors PHYSICS, CONDENSED MATTER-
CiteScore
6.70
自引率
9.80%
发文量
119
期刊介绍: Journal of Semiconductors publishes articles that emphasize semiconductor physics, materials, devices, circuits, and related technology.
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