2017
DOI: 10.1364/oe.25.008986
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Integration of bow-tie plasmonic nano-antennas on tapered fibers

Abstract: In this article, a new and flexible approach to control the electric field enhancement of bow-tie nano-antennas by integrating them on the lateral of a tapered optical fiber is proposed. The device is driven by a Q-switched laser and the performance of a fabricated nano-antenna in a quartz slide is tested by a Surface Enhanced Raman Scattering (SERS) experiment. A refractive index sensing experiment is also performed and a sensitivity of (240 ± 30) nm/RIU is found in the 1.33-1.35 index range.

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Cited by 34 publications
(14 citation statements)
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“…We have indirectly measured the electric field enhancement of nano-antennas by using Raman spectroscopy (the Raman intensity is proportional to the fourth power of the electric field), but only at room temperature 44 . The Raman equipment used has an internal laser and optical parts that could be damaged at high temperatures and, moreover, the equipment does not have enough room to accommodate heaters to control the temperature of the antennas.…”
Section: Discussionmentioning
confidence: 99%
“…We have indirectly measured the electric field enhancement of nano-antennas by using Raman spectroscopy (the Raman intensity is proportional to the fourth power of the electric field), but only at room temperature 44 . The Raman equipment used has an internal laser and optical parts that could be damaged at high temperatures and, moreover, the equipment does not have enough room to accommodate heaters to control the temperature of the antennas.…”
Section: Discussionmentioning
confidence: 99%
“…So, antennas have been making a resonant in (IR) and microwave region when it is designed as a nanoscale metallic with a sharpened will progress locally enhanced (E-field) [14]. So, when fabricated two a nanoscale triangles tip to tip metallic with a small distance gap between them this is a bowtie nanoantenna which gives a high electric field intensity in the air of the gab [14,15]. Because of a localized surface Plasmon excitation [15] So, by varying the gap distance between the two nanostructures we can be controlling the enhancement of electric field around the gap, and the resonance frequency, s-parameter, and wavelength.…”
Section: Gap Effectmentioning
confidence: 99%
“…So, when fabricated two a nanoscale triangles tip to tip metallic with a small distance gap between them this is a bowtie nanoantenna which gives a high electric field intensity in the air of the gab [14,15]. Because of a localized surface Plasmon excitation [15] So, by varying the gap distance between the two nanostructures we can be controlling the enhancement of electric field around the gap, and the resonance frequency, s-parameter, and wavelength. This can be shown in This result shows a correlation between the gap and resonance frequency when the light is parallel polarized to the axis along the pairs that combine to the nanoparticle center [14].…”
Section: Gap Effectmentioning
confidence: 99%
“…Bowtie nanoantennas (BAs) [14], [16], [30]- [35] and bowtie aperture antennas (BAAs) [36]- [41] are two common examples of widely used optical antennas. BAs consist of two triangular nanoparticles arranged tip-to-tip with a very small gap between them.…”
Section: Introductionmentioning
confidence: 99%