M
Masashi Miyata
Researcher at Nippon Telegraph and Telephone
Publications - 29
Citations - 430
Masashi Miyata is an academic researcher from Nippon Telegraph and Telephone. The author has contributed to research in topics: Plasmon & Surface plasmon. The author has an hindex of 9, co-authored 25 publications receiving 339 citations. Previous affiliations of Masashi Miyata include Osaka University.
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Full-Color Subwavelength Printing with Gap-Plasmonic Optical Antennas
TL;DR: It is demonstrated that the individual-antenna properties that feature strong light absorption at two distinct frequencies can be encoded into a single subwavelength-pixel, enabling the creation of saturated colors, as well as a dark color in reflection, at the optical diffraction limit.
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Multi-spectral plasmon induced transparency via in-plane dipole and dual-quadrupole coupling.
TL;DR: An approach based on dipole and dual-quadrupole coupling to construct a planar metamaterial supporting multi-spectral plasmon induced transparency that leads to two transmission windows even in the absorption linewidth of the dipole.
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High-Sensitivity Color Imaging Using Pixel-Scale Color Splitters Based on Dielectric Metasurfaces
TL;DR: In this paper, a color image sensor employing absorptive color filters exhibits low overall light transmission, resulting in limited signal levels per sensor pixel, and this issue is becoming critical beca...
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Gap Plasmon Resonance in a Suspended Plasmonic Nanowire Coupled to a Metallic Substrate.
TL;DR: This study demonstrates that the NW supports strong gap plasmon resonances of various gap sizes including single-nanometer-scale gaps, and illustrates that the suspended NW geometry is capable of constructing plAsmonic coupled systems dominated by quasi-electrostatics.
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Compound-eye metasurface optics enabling a high-sensitivity, ultra-thin polarization camera.
TL;DR: A polarization imaging system based on compound-eye metasurface optics that overcomes both efficiency and size limitations of conventional polarization cameras and could pave the way toward the widespread adoption of polarization imaging in applications in which available light is limited and strict size constraints exist.