金属核Al2O3纳米壳的等离子体性质

Q3 Engineering Micro and Nanosystems Pub Date : 2021-10-06 DOI:10.2174/1876402913666211006153430
J. Katyal
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引用次数: 0

摘要

Al是深紫外和更长波长范围等离子体应用的有前途的候选者。但是很难具有纯铝纳米结构,因为它很容易被氧化形成Al2O3薄层。本文评估了金属壳(Al-Al2O3和Au-Al2O3)上氧化物层对单核壳和二聚体核壳结构的场增强,并展示了氧化物层在SERS中的潜力。用时域有限差分法(FDTD)评估了单核和二聚物Al-Al2O3以及Au-Al2O3纳米结构的LSPR和场增强。结果表明,在改变Al2O3壳层的内外半径时,等离子体共振是可调谐的。随着壳层厚度的增加,观察到红移和增强的减少,而随着核尺寸的增加,在Au-Al2O3的情况下,增强增加,并且由于四极的贡献,Al-Al2O3减少。但是,在比较相同粒度的Au-Al2O3和Al-Al2O3时,Al-Al2O3表现出更大的增强,因为Au必须与其带间跃迁竞争。通过优化壳的厚度和核的尺寸,可以得出结论,Al2O3的超薄壳可以给予更高的增强。与Au-Al2O3相比,Al作为核心金属的增强作用增加。由于单个Al-Al2O3纳米壳显示出巨大的增强,我们考虑了两个相同纳米壳的多聚体构型。由于两个纳米壳之间的耦合,在UV区域观察到Al-Al2O3二聚体纳米壳的增强因子大幅增加~1012。
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Plasmonic Properties of Al2O3 Nanoshell with a Metallic Core
Al is the promising candidate for the deep UV and longer wavelength range plasmonic applications. But it is difficult to have the pure Aluminium nanostructure as it is easily oxidized forming a thin layer of Al2O3. In this paper we have evaluated the field enhancement of oxide layer on metallic shell (Al-Al2O3 and Au- Al2O3) for single and dimer core-shell configuration and shown potential of oxide layer in SERS. The Finite Difference Time Domain (FDTD) has been used to evaluated the LSPR and field enhancement of single and dimer Al-Al2O3 and Au- Al2O3 nanostructure. The results exhibit the tunable plasmon resonance on varying the inner and outer radii of the Al2O3 shell. A redshift and decrease in enhancement were observed as shell thickness increases whereas on increasing the core size the enhancement gets increased in the case of Au-Al2O3 and gets a decrease in Al-Al2O3 due to quadrupole contribution. But on comparing the Au-Al2O3 with Al-Al2O3 for the same particle size, Al-Al2O3 shows larger enhancement because Au has to compete with its inter band transition. By optimizing the thickness of the shell and core size, it can be concluded that an ultrathin shell of Al2O3 can give higher enhancement. With Al as a core metal the enhancement increases as compared to Au-Al2O3. Since a single Al-Al2O3 nanoshell has shown a huge enhancement we have considered the multimer configuration of two identical nanoshell. Due to coupling between two nanoshell a huge increase in enhancement factor ~1012 was observed for Al-Al2O3 dimer nanoshell in the UV region.
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来源期刊
Micro and Nanosystems
Micro and Nanosystems Engineering-Building and Construction
CiteScore
1.60
自引率
0.00%
发文量
50
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