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Volume 26 - ICOP & ICPET 2020
ICOP & ICPET _ INPC _ ICOFS 2020, 26 - ICOP & ICPET 2020: 425-428 |
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Dehghani Firouzabadi M, Nikoufard M, Pahlavanshamsi M R. Investigation of Hybrid Plasmonic Waveguide with DDMEBT Polymer. ICOP & ICPET _ INPC _ ICOFS 2020; 26 :425-428
URL: http://opsi.ir/article-1-2079-en.html
URL: http://opsi.ir/article-1-2079-en.html
1- Department of Ceramic Engineering, Imam Khomeini Technical College of Meybod, Yazd, Iran
2- Department of Electronics, Faculty of Electrical and Computer Engineering, University of Kashan
2- Department of Electronics, Faculty of Electrical and Computer Engineering, University of Kashan
Abstract: (1598 Views)
Beyond the diffraction limit, plasmonic waveguides (PWs) have the ability to manipulate light at nanoscale structures through surface plasmon polaritons (SPPs) at metal-dielectric interface. Much interest has been paid to PWs because they are promising candidates for developing highly-dense integrated photonic circuits. Hybrid plasmonic waveguides (HPWs) are recent novel type of PWs, which have shown a favorable balance between mode confinement and propagation loss. In this paper a multi-layer HPW including DDMEBT dielectric layer is proposed and it's modal properties such as effective refractive index, propagation length and effective mode area using finite element method (FEM) is calculated. Also performance of HPW is evaluated using figure of merit (FoM). In this waveguide effective mode area is achieved in the range of 0.027-0.069𝝁m2. Such waveguides structures can be utilized for ultra-compact nano-photonic devices.
Keywords: Effective refractive index, Effective area, Figure of merit, Hybrid plasmonic waveguide, Propagation length.
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