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A. Ahmadivand, B. Gerislioglu, Z. Ramezani (2019)
Generation of magnetoelectric photocurrents using toroidal resonances: a new class of infrared plasmonic photodetectors.Nanoscale
Ming Zhang, Jiawen Fang, Fei Zhang, Junyan Chen, Honglin Yu (2017)
Ultra-narrow band perfect absorbers based on Fano resonance in MIM metamaterialsOptics Communications, 405
Wayne Yang, Y. Chau, S. Jheng (2013)
Analysis of transmittance properties of surface plasmon modes on periodic solid/outline bowtie nanoantenna arraysPhysics of Plasmas, 20
G. Hanson (2007)
Dyadic Green's functions and guided surface waves for a surface conductivity model of grapheneJournal of Applied Physics, 103
P. Johnson, R. Christy (1972)
Optical Constants of the Noble MetalsPhysical Review B, 6
(2022)
Appl Phys 50:195101 Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations
Masaaki Oshita, Hidetoshi Takahashi, Y. Ajiki, T. Kan (2020)
Reconfigurable Surface Plasmon Resonance Photodetector with a MEMS Deformable CantileverACS Photonics, 7
(2019)
PanditN PNP (2019) Center frequency and bandwidth reconfigurable spoof surface plasmonic metamaterial band-pass filter
Chung-Ting Chao, Yuan-Fong Chau, H. Chiang (2021)
Multiple Fano resonance modes in an ultra-compact plasmonic waveguide-cavity system for sensing applicationsResults in Physics
R. Jaiswal, Nidhi Pandit, N. Pathak (2019)
Center Frequency and Bandwidth Reconfigurable Spoof Surface Plasmonic Metamaterial Band-Pass FilterPlasmonics
Yixin Fan, Y. Qian, Shan Yin, Dongxia Li, Mingzhu Jiang, Xiaoqing Lin, F. Hu (2019)
Multi-band tunable terahertz bandpass filter based on vanadium dioxide hybrid metamaterialMaterials Research Express, 6
M. Soheilifar (2018)
Wideband optical absorber based on plasmonic metamaterial cross structureOptical and Quantum Electronics, 50
Y. Chau, H. Yeh, D. Tsai (2010)
A New Type of Optical Antenna: Plasmonics Nanoshell Bowtie Antenna with Dielectric HoleJournal of Electromagnetic Waves and Applications, 24
Z. Vafapour (2019)
Polarization-Independent Perfect Optical Metamaterial Absorber as a Glucose Sensor in Food Industry ApplicationsIEEE Transactions on NanoBioscience, 18
Y. Chau, C. Jheng, Shen-Fen Joe, Shinn-Fwu Wang, Wayne Yang, S. Jheng, Yuh-Sien Sun, Yi Chu, Jeng-Hua Wei (2013)
Structurally and materially sensitive hybrid surface plasmon modes in periodic silver-shell nanopearl and its dimer arraysJournal of Nanoparticle Research, 15
Kai Wang, Haifeng Hu, Shan Lu, Meihua Jin, Yanjie Wang, T. He (2020)
Visible and near-infrared dual-band photodetector based on gold–silicon metamaterialApplied Physics Letters, 116
Raghwendra Kumar, Raghwendra Kumar, S. Ramakrishna (2019)
Simple trilayer metamaterial absorber associated with Fano-like resonanceJournal of Nanophotonics, 14
M. Elshorbagy, A. Cuadrado, G. González, F. González, J. Alda (2019)
Performance Improvement of Refractometric Sensors Through Hybrid Plasmonic–Fano ResonancesJournal of Lightwave Technology, 37
A. Lochbaum, A. Dorodnyy, U. Koch, Stefan Koepfli, Sebastian Volk, Y. Fedoryshyn, V. Wood, J. Leuthold (2020)
Compact Mid-Infrared Gas Sensing Enabled by an All-Metamaterial Design.Nano letters
Y. Chau, J. Jiang, Chung-Ting Chao, H. Chiang, C. Lim (2016)
Manipulating near field enhancement and optical spectrum in a pair-array of the cavity resonance based plasmonic nanoantennasJournal of Physics D: Applied Physics, 49
I. Malitson (1965)
Interspecimen Comparison of the Refractive Index of Fused SilicaJournal of the Optical Society of America, 55
Zhihui He, Chunjiang Li, Wei-wei Cui, Weiwei Xue, Zhenxiong Li, L. Pu, Jiaojiao Feng, Xintao Xiao, Xuyang Wang, Yajie Liu, Qirui Zou, Yufei Yao, Yixuan Niu, Mengyuan Wang (2020)
Dual-Fano resonances and sensing properties in the crossed ring-shaped metasurfaceResults in Physics
C. Bauer, H. Giessen (2020)
Tailoring the plasmonic Fano resonance in metallic photonic crystalsNanophotonics, 9
Y. Chau, C. Lim, Chien-Ying Chiang, N. Voo, Nur Idris, Siew Chai (2016)
Tunable silver-shell dielectric core nano-beads array for thin-film solar cell applicationJournal of Nanoparticle Research, 18
Yuan-Fong Chau, Chung-Ting Chao, Siti Jumat, M. Kooh, Roshan Thotagamuge, C. Lim, H. Chiang (2021)
Improved Refractive Index-Sensing Performance of Multimode Fano-Resonance-Based Metal-Insulator-Metal NanostructuresNanomaterials, 11
Y. Chau, Chung-Ting Chao, Jhin-Yu Rao, H. Chiang, C. Lim, Ren Lim, N. Voo (2016)
Tunable Optical Performances on a Periodic Array of Plasmonic Bowtie Nanoantennas with Hollow CavitiesNanoscale Research Letters, 11
Behrokh Beiranvand, A. Sobolev, Arash Sheikhaleh (2020)
A proposal for a dual-band tunable plasmonic absorber using concentric-rings resonators and mono-layer grapheneOptik, 223
Xiyu Long, Ming Zhang, Zheng-wei Xie, Ming-jun Tang, Ling Li (2020)
Sharp Fano resonance induced by all-dielectric asymmetric metasurfaceOptics Communications, 459
Zhihui He, Weiwei Xue, Wei-wei Cui, Chunjiang Li, Zhenxiong Li, L. Pu, Jiaojiao Feng, Xintao Xiao, Xuyang Wang, Gang Li (2020)
Tunable Fano Resonance and Enhanced Sensing in a Simple Au/TiO2 Hybrid MetasurfaceNanomaterials, 10
You Ho, W. Chen, Yao-Wei Huang, P. Wu, Ming Tseng, Y. Wang, Y. Chau, D. Tsai (2012)
Tunable plasmonic resonance arising from broken-symmetric silver nanobeads with dielectric coresJournal of Optics, 14
Yang Yuhua, Yongqing Xu, Binzhen Zhang, Junping Duan, Li Yan, Hongcheng Xu, Yunpeng Liu, Yanan Shi (2019)
Investigating flexible band-stop metamaterial filter over THzOptics Communications
Fatemeh Tavakoli, F. Zarrabi, H. Saghaei (2019)
Modeling and analysis of high-sensitivity refractive index sensors based on plasmonic absorbers with Fano response in the near-infrared spectral region.Applied optics, 58 20
Shuyuan Xiao, Tao Wang, Xiaoyun Jiang, Xicheng Yan, L. Cheng, Boyun Wang, Chen Xu (2017)
Strong interaction between graphene layer and Fano resonance in terahertz metamaterialsJournal of Physics D: Applied Physics, 50
Yuan-Fong Chau, C. Lim, Chuanyo Lee, H. Huang, Chun-Ting Lin, Roshan Thotagamuge, V. Yoong, H. Chiang (2016)
Tailoring surface plasmon resonance and dipole cavity plasmon modes of scattering cross section spectra on the single solid-gold/gold-shell nanorodJournal of Applied Physics, 120
In this paper, a metal–insulator-metal (MIM) plasmonic absorber consisting of asymmetric double bars with bent arms located on top of a silica layer coated on a metal film is proposed, and its resonant features are analyzed. The suggested structure supports both Fano and dipole perfect absorption resonances at the near-infrared region (NIR). The asymmetry introduced into the structure can be induced by changing the bending angle or rotation angle of one of the antennas, while the other one remains fixed. Simulation results demonstrate that by applying both asymmetry factors to the structure, one can have two individual Fano peaks at the same time. It is shown that the magnitude, central wavelength, and line width of the Fano peaks are adjustable by controlling the geometrical parameters of the structure. It is also indicated that the quality factor (Q-factor) of the Fano resonance is inversely related to the degree of asymmetry introduced into the structure. According to the simulations, an ultra-narrow resonance peak with a bandwidth of 1.87 nm at the wavelength of 710 nm (corresponding to a Q-factor of 387) can be obtained by controlling the geometrical parameters. It is also discussed that the absorptivity of Fano and the dipole peaks can be adjusted inversely, by manipulating the grapheme chemical potential. The ratio of the absorptivity to the chemical potential of graphene about 275%/eV and 226%/eV is calculated for the Fano peak and dipole peak, respectively. Accordingly, the presented structure is an adjustable NIR absorber with a fully tunable absorption spectrum which can be utilized in various applications from tunable reflectors and photo-detectors to ultra-narrowband and broadband optical modulators.
Plasmonics – Springer Journals
Published: Aug 1, 2022
Keywords: MIM; Plasmonic; Absorber; Fano; Dipole
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