D
Daniel R. Mason
Researcher at Seoul National University
Publications - 18
Citations - 419
Daniel R. Mason is an academic researcher from Seoul National University. The author has contributed to research in topics: Plasmon & Surface plasmon. The author has an hindex of 12, co-authored 18 publications receiving 391 citations. Previous affiliations of Daniel R. Mason include Pohang University of Science and Technology.
Papers
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Enhanced resolution beyond the Abbe diffraction limit with wavelength-scale solid immersion lenses
TL;DR: From full three-dimensional, finite-difference time-domain calculations, it is demonstrated that the FWHM of the focal spot of an objective-lens-nSIL system can be reduced by greater than 25% compared to a regular macroscopic SIL.
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Enhanced Light Trapping and Power Conversion Efficiency in Ultrathin Plasmonic Organic Solar Cells: A Coupled Optical-Electrical Multiphysics Study on the Effect of Nanoparticle Geometry
TL;DR: In this paper, the optical absorption capability of a solar cell could be maintained with the incorporation of localized surface plasmon (LSP) resonances such as strong light trapping, large scattering cross-section, and giant electric field enhancement for the more efficient harvesting of solar energy.
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Direct Optical Probing of Transverse Electric Mode in Graphene
TL;DR: For the first time, it is experimentally prove an existence of the TE mode by its direct optical probing, demonstrating significant coupling to an incident wave in electrically doped multilayer graphene sheet at room temperature.
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Plasmonic Excitations of 1D Metal-Dielectric Interfaces in 2D Systems: 1D Surface Plasmon Polaritons
TL;DR: It is shown for the first time that 1D metal-dielectric interfaces support a fundamental 1D plasmonic mode (1DSPP) which exhibits cutoff behavior that provides dramatically improved light confinement in 2D systems.
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Direct Optical Probing of Transverse Electric Mode in Graphene
TL;DR: In this article, the transverse-electric (TE) mode supported by graphene has been investigated by direct optical probing, demonstrating significant coupling to an incident wave in electrically doped multilayer graphene sheet at room temperature.