基于Au纳米平行双棒超表面阵列的双Fano共振和折射率传感器特性研究 -

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基于Au纳米平行双棒超表面阵列的双Fano共振和折射率传感器特性研究

1.
中北大学仪器科学与动态测试教育部重点实验室, 山西太原 030051
2.
中北大学软件学院, 山西太原 030051
3.
中北大学信息与通信工程学院, 山西太原 030051
4.
岭南师范学院物理科学与技术学院, 广东湛江 524048

中图分类号:TP394.1;TH691.9
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出版历程
- 收稿日期:2023-04-23
- 修回日期:2023-05-18
- 网络出版日期:2023-06-17

Double Fano resonance and refractive index sensors based on parallel-arranged Au nanorod dimer metasurface arrays

doi:10.37188/CO.EN-2023-0008

1.
Key Laboratory of Instrumentation Science & Dynamic Measurement of Ministry of Education, North University of China, Taiyuan 030051, China
2.
School of Software, North University of China, Taiyuan 030051, China
3.
School of Information and Communication Engineering, North University of China, Taiyuan 030051, China
4.
School of Physical Science and Technology, Lingnan Normal University, Zhanjiang 524048, China

Funds:Supported by the National Natural Science Foundation of China (No.12004150); Scientific and Technological Innovation Programs of Higher Education Institutions in Shanxi (No. 2020L0316); the Guangdong Basic and Applied Basic Research Foundation (No. 2020A1515110998)

More Information

Author Bio:
ZHANG Zhi-dong (1985—), male, born in Jingle, Shanxi Province, Doctor, graduate student supervisor, received his Ph. D in electromagnetic field and microwave technology from Southwest Jiaotong University in 2014. He is currently an associate Professor at the school of Instrumentation and Electronics of North University of China，and he is the member of the Key Laboratory of Instrumentation Science & Dynamic Measurement of Ministry of Education. His research interests include micro/nanosensors and nanophotonics. E-mail:zdzhang@nuc.edu.cn
LIU Yan-Li (1985—), female, born in huaibei, Anhui Province, Doctor, received her Ph. D degree from North University of China. She is an Associate Professor at the School of Information and Communication Engineering, of North University of China. Her current research interests include micro/nano-photonics. E-mail:565347436@qq.com
ZHU Xu-peng (1992—), male, born in Tianshui, Gansu Province, Doctor, received his Ph. D degree from Hunan University in 2018. Currently, he is an associate professor in physics at the School of Physics Science and Technology of Lingnan Normal University. His current research is focused on the surface plasmon effects of multiscale metallic micro–nanostructures. E-mail:zhuxp18@lingnan.edu.cn

Corresponding author:565347436@qq.com;zhuxp18@lingnan.edu.cn

摘要

摘要:
为了研究超表面结构的耦合及折射率传感特性，设计了一种由两种长度不同的纳米棒组成的二聚体结构，并研究该结构的透射光谱，共振峰处的电场和电荷分布以及结构参数对透射光谱的影响。本文采用有限元法对光学性能进行仿真分析，采用准静态逼近模型解释了平行双纳米棒结构的耦合机理。在共振波长上模拟电场分布,分析电子振动模式，在透射光谱中出现了不对称线型的双Fano共振。结果表明,双Fano共振是由纳米棒和衬底之间的耦合作用产生的，可以通过结构参数和周围介质的折射率来调控，且基于Fano共振的折射率灵敏度最大可达1.137 μm/RIU。这些研究结果为设计等离激元传感器提供了理论依据。
- 等离激元超表面/
- Au纳米棒/
- 双Fano共振/
- 折射率传感器
Abstract:
In order to study the coupling and refractive index sensing properties of a metasurface, asymmetric parallel nanorod dimers consisting of two nanorods with different lengths was proposed and designed. In this paper, the finite element method is used to simulate the optical properties and a quasi-static approximation model is used to explain the coupling mechanism of double parallel nanorods. The transmission spectra, electric field at the resonant peak, charge distribution and the influence of structural parameters on the transmission spectra are studied. The electric field distribution is simulated at the resonance wavelength, the electron vibration mode is analyzed, and asymmetric double Fano resonance appears in the transmission spectrum. The results show that the double Fano resonance is generated by the coupling between the nanorods and the substrate, and the double Fano resonance can be regulated by the structural parameters and the refractive index of the surrounding medium. The sensitivity of the refractive index based on the Fano resonance can reach 1.137 μm/RIU. These results provide a theoretical basis for the design of a surface plasmon refractive index sensor.
- plasmonic metasurfaces/
- Au nanorods/
- double Fano resonance/
- refractive index sensor

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Figure 1.(a) The metasurface array of double parallel nanorods with different lengths. (b) The planar graph of this structure

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Figure 2.The interactive electric energy between the moment of the double nanorods’ dipole

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Figure 3.Transmittance spectra of the nanorod dimer nanostructures, where the distances of the short nanorod’s center deviating from the long nanorod’s center is fixed as 0 nm and 80 nm

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Figure 4.The distribution of the normalized square of the electric field (|E|²) and the charge density of the nanorod dimer for the symmetry structure peak atAandC,and dip atBandDwhereS= 0 nm at (a)λ_A= 2.32 μm, (b)λ_B= 2.36 μm, (c)λ_C= 2.92 μm, and (d)λ_D= 3.00 μm

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Figure 5.The distribution of the normalized square of electric field (|E|²) and the charge density of the double parallel nanorods for symmetry structure at the peakE,G,Iand dipsF,H,Jwith the parameters= 80 nm atλ_E= 2.26 mm (a),λ_F= 2.30 mm (b),λ_G= 2.36 mm (c),λ_H= 2.90 mm (d),λ_I= 2.98 mm (e), andλ_J= 3.00 mm (f).

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Figure 6.Transmission spectra of the double parallel nanorods: (a)s= 0, 20, 40, 60, and 80 nm with fixedL₂= 800 nm,w= 100 nm,L₁= 400 nm,t= 50 nm andg= 20 nm. (b)L₁= 400, 420, 440, 460, and 480 nm with fixedS= 0 nm,w= 100 nm,L₂= 800 nm,t= 50 nm andg= 20 nm.

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Figure 7.Transmission spectra of the double parallel nanorods. (a)g= 20, 40, 60, 80, 100 nm with fixed s = 0 nm,L₁= 400 nm,w= 100 nm,L₂= 800 nm andt= 50 nm. (b)θ= 0°, 30°, 60°, and 90° with fixeds= 0 nm,L₁= 400 nm, w= 100 nm,L₂= 800 nm,t= 50 nm, andg= 20 nm

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Figure 8.(a) Transmission spectra varying with different refractive indexn. (b) Relationship between the resonance dip wavelengthλ₁andλ₂and the refractive index. (c) Relationship between resonance dip wavelength changeδλand the change in the refractive indexδn

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Table 1.Comparison of sensitivity of different methods

	Sensitivity (nm/RIU)	FoM	Ref.
1	912	19	[36]
2	1109		[37]
3	655	20	[38]
4	1380	18.9	[39]
	1055	19.5	[40]
5	1137		This paper

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