Optical slot antennas and their applications to photonic devices
We present optical slot antennas and their applications to photonic devices. We show that metallic nanoslots have the properties of a slot antenna by measuring the transmission spectra and far-field radiation patterns and then prove that they can be physically regarded as magnetic dipoles in the opt...
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Published in | Nanophotonics (Berlin, Germany) Vol. 7; no. 10; pp. 1617 - 1636 |
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Main Authors | , , , |
Format | Journal Article |
Language | English |
Published |
De Gruyter
25.10.2018
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Subjects | |
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Abstract | We present optical slot antennas and their applications to photonic devices. We show that metallic nanoslots have the properties of a slot antenna by measuring the transmission spectra and far-field radiation patterns and then prove that they can be physically regarded as magnetic dipoles in the optical region. Additionally, we can generate directional radiations from optical slot antennas by adopting the geometry of radiofrequency Yagi-Uda antenna and properly adding auxiliary elements called reflectors and directors to a single slot antenna. We present two cases as the applications of optical slot antennas. One is the integration of slot antennas to plasmonic waveguides. This combination can be used as a basic unit for optical interconnection to free space and plasmonic via in multilayered plasmonic structures. The other is the integration of slot antennas to the electrode of light-emitting diodes (LEDs). Using slot antennas, we can control the polarization and direction of emissions from LEDs. Besides the above-mentioned two cases, we expect that optical slot antennas have possible applications to various photonic devices and can be essential elements in future integrated photonic circuits with nanometer scales. |
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AbstractList | Abstract
We present optical slot antennas and their applications to photonic devices. We show that metallic nanoslots have the properties of a slot antenna by measuring the transmission spectra and far-field radiation patterns and then prove that they can be physically regarded as magnetic dipoles in the optical region. Additionally, we can generate directional radiations from optical slot antennas by adopting the geometry of radiofrequency Yagi-Uda antenna and properly adding auxiliary elements called reflectors and directors to a single slot antenna. We present two cases as the applications of optical slot antennas. One is the integration of slot antennas to plasmonic waveguides. This combination can be used as a basic unit for optical interconnection to free space and plasmonic via in multilayered plasmonic structures. The other is the integration of slot antennas to the electrode of light-emitting diodes (LEDs). Using slot antennas, we can control the polarization and direction of emissions from LEDs. Besides the above-mentioned two cases, we expect that optical slot antennas have possible applications to various photonic devices and can be essential elements in future integrated photonic circuits with nanometer scales. We present optical slot antennas and their applications to photonic devices. We show that metallic nanoslots have the properties of a slot antenna by measuring the transmission spectra and far-field radiation patterns and then prove that they can be physically regarded as magnetic dipoles in the optical region. Additionally, we can generate directional radiations from optical slot antennas by adopting the geometry of radiofrequency Yagi-Uda antenna and properly adding auxiliary elements called reflectors and directors to a single slot antenna. We present two cases as the applications of optical slot antennas. One is the integration of slot antennas to plasmonic waveguides. This combination can be used as a basic unit for optical interconnection to free space and plasmonic via in multilayered plasmonic structures. The other is the integration of slot antennas to the electrode of light-emitting diodes (LEDs). Using slot antennas, we can control the polarization and direction of emissions from LEDs. Besides the above-mentioned two cases, we expect that optical slot antennas have possible applications to various photonic devices and can be essential elements in future integrated photonic circuits with nanometer scales. |
Author | Park, Q-Han Kim, Jineun Roh, Young-Geun Park, Yeonsang |
Author_xml | – sequence: 1 givenname: Yeonsang orcidid: 0000-0002-9746-8026 surname: Park fullname: Park, Yeonsang email: yeonsang.park@samsung.com organization: Samsung Advanced Institute of Technology, Imaging Device Lab, Samsung-ro 130, Suwon 16678, Korea – sequence: 2 givenname: Jineun surname: Kim fullname: Kim, Jineun organization: Samsung Advanced Institute of Technology, Imaging Device Lab, Samsung-ro 130, Suwon 16678, Korea – sequence: 3 givenname: Young-Geun surname: Roh fullname: Roh, Young-Geun organization: Samsung Advanced Institute of Technology, Imaging Device Lab, Samsung-ro 130, Suwon 16678, Korea – sequence: 4 givenname: Q-Han surname: Park fullname: Park, Q-Han organization: Department of Physics, Korea University, Anam-ro 145, Seoul 02841, Korea |
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Snippet | We present optical slot antennas and their applications to photonic devices. We show that metallic nanoslots have the properties of a slot antenna by measuring... Abstract We present optical slot antennas and their applications to photonic devices. We show that metallic nanoslots have the properties of a slot antenna by... |
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StartPage | 1617 |
SubjectTerms | integration to photonic devices magnetic dipole metallic nanoslot optical slot antenna optical slot Yagi-Uda antenna |
Title | Optical slot antennas and their applications to photonic devices |
URI | http://www.degruyter.com/doi/10.1515/nanoph-2018-0045 https://doaj.org/article/bb28b70a7a054182bd877344b5918780 |
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