Dataset to support the publication 'Plasmonic anapole metamaterial for refractive index sensing'
Dataset to support the publication 'Plasmonic anapole metamaterial for refractive index sensing'
This Dataset supports the publication of 'Plasmonic anapole metamaterial for refractive index sensing' published in PhotoniX (issn: 2662-1991). DOI of the article: 10.1186/s43074-022-00069-x
The data includes related information to Fig 2, 3 and 4.
Fig. 2 shows Electromagnetic responses of two components of the plasmonic anapole metamaterial. (b) transmission (blue curve) and reflection (red curve) spectra, (c) multipole decomposition and phases of electric dipole and toroidal dipole moments, and (d) normalized yz-plane electric field and magnetic field distributions of the dumbbell-perforated gold film placed on the dielectric substrate.
Fig. 3 shows Electromagnetic responses of the plasmonic anapole metamaterial. (a) Measured and (b) simulated transmission (blue curve) and reflection (red curve) spectra, (c) multipole decomposition, (d) phases of electric dipole and toroidal dipole moments, and (e) normalized electric field and magnetic field
distributions of the plasmonic anapole metamaterial in the yz-plane and the xy-plane. Grey dotted lines in Fig. 3b-d denote the resonant wavelength of anapole mode. White dashed arrows depict the orientations of the magnetic field. The xy cut plane is located in the middle of the upper dumbbell-perforated gold film.
All the geometric parameters are identical to those in Fig. 2.
Fig. 4 shows Refractive index sensing application of the plasmonic anapole metamaterial. (a) Measured and (b) simulated transmission and reflection spectra with variable ambient refractive index from 1.30 to 1.39 with a step of 0.01. Dark (light) blue and red correspond to transmission and reflection at refractive index
n = 1.30 (1.39). (c) The resonant wavelengths of the anapole mode from experimental and simulation results as functions of the ambient refractive index. The black solid lines represent the linear fitting results.
University of Southampton
Yao, Jin
d0e505b8-46a9-4c2a-a278-35ff4f85f7da
Ou, Jun-Yu
3fb703e3-b222-46d2-b4ee-75f296d9d64d
Savinov, Vassili
147c7954-4636-4438-a305-cd78539f7c0a
Chen, Mu Ku
7e685629-2ed6-4159-b358-77c106a26c4d
Kuo, Hsin Yu
86fc31d8-6b81-4948-a5e6-bfd9da29062a
Zheludev, Nikolai
32fb6af7-97e4-4d11-bca6-805745e40cc6
Tsai, Din Ping
a8d03877-49f9-4376-abef-468800938efe
Yao, Jin
d0e505b8-46a9-4c2a-a278-35ff4f85f7da
Ou, Jun-Yu
3fb703e3-b222-46d2-b4ee-75f296d9d64d
Savinov, Vassili
147c7954-4636-4438-a305-cd78539f7c0a
Chen, Mu Ku
7e685629-2ed6-4159-b358-77c106a26c4d
Kuo, Hsin Yu
86fc31d8-6b81-4948-a5e6-bfd9da29062a
Zheludev, Nikolai
32fb6af7-97e4-4d11-bca6-805745e40cc6
Tsai, Din Ping
a8d03877-49f9-4376-abef-468800938efe
Yao, Jin, Ou, Jun-Yu, Savinov, Vassili, Chen, Mu Ku, Kuo, Hsin Yu, Zheludev, Nikolai and Tsai, Din Ping
(2022)
Dataset to support the publication 'Plasmonic anapole metamaterial for refractive index sensing'.
University of Southampton
doi:10.5258/SOTON/D2387
[Dataset]
Abstract
This Dataset supports the publication of 'Plasmonic anapole metamaterial for refractive index sensing' published in PhotoniX (issn: 2662-1991). DOI of the article: 10.1186/s43074-022-00069-x
The data includes related information to Fig 2, 3 and 4.
Fig. 2 shows Electromagnetic responses of two components of the plasmonic anapole metamaterial. (b) transmission (blue curve) and reflection (red curve) spectra, (c) multipole decomposition and phases of electric dipole and toroidal dipole moments, and (d) normalized yz-plane electric field and magnetic field distributions of the dumbbell-perforated gold film placed on the dielectric substrate.
Fig. 3 shows Electromagnetic responses of the plasmonic anapole metamaterial. (a) Measured and (b) simulated transmission (blue curve) and reflection (red curve) spectra, (c) multipole decomposition, (d) phases of electric dipole and toroidal dipole moments, and (e) normalized electric field and magnetic field
distributions of the plasmonic anapole metamaterial in the yz-plane and the xy-plane. Grey dotted lines in Fig. 3b-d denote the resonant wavelength of anapole mode. White dashed arrows depict the orientations of the magnetic field. The xy cut plane is located in the middle of the upper dumbbell-perforated gold film.
All the geometric parameters are identical to those in Fig. 2.
Fig. 4 shows Refractive index sensing application of the plasmonic anapole metamaterial. (a) Measured and (b) simulated transmission and reflection spectra with variable ambient refractive index from 1.30 to 1.39 with a step of 0.01. Dark (light) blue and red correspond to transmission and reflection at refractive index
n = 1.30 (1.39). (c) The resonant wavelengths of the anapole mode from experimental and simulation results as functions of the ambient refractive index. The black solid lines represent the linear fitting results.
Text
Readme_Dataset_Plasmonic_Anapole_Metamaterial_for_Refractive_Index_Sensing.pdf
- Text
Spreadsheet
ResearchData_Anapole_sensor.xlsx
- Text
More information
Published date: 1 November 2022
Identifiers
Local EPrints ID: 471368
URI: http://eprints.soton.ac.uk/id/eprint/471368
PURE UUID: c5d88539-872c-4423-a16a-bcf8273e9818
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Date deposited: 04 Nov 2022 17:34
Last modified: 06 Jun 2024 01:49
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Contributors
Creator:
Jin Yao
Creator:
Jun-Yu Ou
Creator:
Vassili Savinov
Creator:
Mu Ku Chen
Creator:
Hsin Yu Kuo
Creator:
Nikolai Zheludev
Creator:
Din Ping Tsai
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