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Cst Microwave Studio Patch Antenna Tutorial.3 rd edition Chapter 14 A John Wiley & Sons, Inc. Balanis (2005) Antenna theory analysis and design. Miyazaki HT (2006) Squeezing visible light waves into a 3-nm-thick and 55-nm-long plasmon cavity. Zhang (2008) Silicon based photonic devices: design, fabrication and characterization. Springer Science, New York chap 2, sec 2.2, pp. In: Plasmonics: Fundamentals and applications. Maier SA (2007) Surface plasmon Polariton at metal/insulator interfaces. Sharma P, Kumar VD (2017) Hybrid insulator metal insulator planar plasmonic waveguide based components. Sharma P, Kumar VD (2018) All optical logic gates using hybrid metal insulator metal plasmonic waveguide. Sharma P, Kumar VD (2016) Investigation of multilayer planar hybrid plasmonic waveguide and bends. Ooi KJA, Bai P, Gu MX, Ang LK (2011) Design of a monopole-antenna-based resonant nanocavity for detection of optical power from hybrid plasmonic waveguides. Ramaccia D, Bilotti F, Toscano A, Massaro A (2011) Efficient and wideband horn nanoantenna. Grosjean T, Mivelle M, Burr GW, Baida FI (2013) Optical horn antennas for efficiently transferring photons from a quantum emitter to a single-mode optical fiber. Pan Z, Guo J (2013) Enhanced optical absorption and electric field resonance in diabolo metal bar optical antennas. Singh R, Rockstuhl C, Menzel C, Meyrath TP, He M, Giessen H, Lederer F, Zhang W (2009) Spiral-type terahertz antennas and the manifestation of the Mushiake principle. ĭregely D, Taubert R, Dorfmuller J, Vogelgesang R, Kern K, Giessen H (2011) 3D optical Yagi-Uda nanoantenna array. Silveira GNM, Wiederhecker GS, Figueroa HEH (2013) Dielectric resonator antenna for applications in nanophotonics. īakker RM, Yuan H-K, Lui Z, Drachev V, Kildishev AV, Shalaev VM, Pederson RH, Gresillon S, Boltasseva A (2008) Enhanced localized fluorescence in plasmonic nanoantennae. īrongersma ML (2008) Plasmonics: engineering optical nanoantennas. Ĭubukcu E, Kort EA, Crozier KB, Capasso F (2006) Plasmonic laser antenna. Appl Phys A Mater Sci Process 117:725–729. Kashyap N, Wani ZA, Jain R, Khusboo, Dinesh Kumar V (2014) Investigation of a nanostrip patch antenna in optical frequencies. Yousefi L, Foster AC (2012) Waveguide-fed optical hybrid plasmonic patch nano-antenna. Progress In Electromagnetics Research Letters 50:85–90. Yousefi L (2014) Highly directive hybrid plasmonic leaky wave optical nano-antenna. Saad-Bin-Alam M, Khalil MI, Rahman A, Chowdhury AM (2015) Hybrid plasmonic waveguide fed broadband nanoantenna for nanophotonic applications. Moreover, it could be used for numerous chip scale applications such as wireless interconnects energy harvesting, photoemission, photo detection, scattering, heat transfer, spectroscopy, and optical sensing. The proposed antenna is practically realizable and can be fabricated using standard semiconductor fabrication process. Since inset-fed antennas are suitable for developing high-gain antenna array, hence further, we examined antenna performance by designing antenna array.
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It is observed, through electromagnetic numerical simulation, that the proposed plasmonic nano patch antenna emits a directional beam with a bandwidth, gain, and efficiency of 0.194 μm, 8.3 dB, and 96% respectively, which are significantly higher than previously reported designs. The proposed antenna is inset fed by an HMIM plasmonic waveguide for achieving proper impedance matching.
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It is designed in a footprint area of 1.7 × 1.175 μm 2 to resonate at 1.55 μm wavelength. This is the first report of a hybrid plasmonic nano patch antenna having metal insulator metal (HMIM) multilayer configuration.