Your search keyword '"Masayoshi Nagao"' showing total 2 results

1. Electron emission properties of gated silicon field emitter arrays driven by laser pulses.

Author

Hidetaka Shimawaki, Masayoshi Nagao, Yoichiro Neo, Hidenori Mimura, Fujio Wakaya, and Mikio Takai

Subjects

*ELECTRON emission, *FIELD emitter arrays, *LASER pulses, *PHOTOEXCITATION, *PHOTOCATHODES, *ELECTRON beams

Abstract

We report optically modulated electron emission from gated p-type silicon field emitter arrays (Si-FEAs). The device's "volcano" structure is designed to control the photoexcitation of electrons by transmitting light through the small gate aperture, thereby minimizing the photogeneration of slow diffusion carriers outside the depletion region in the tip. Compared to that in the dark, the emission current was enhanced by more than three orders of magnitude in the high field region when irradiated with blue laser pulses. Results from the time-resolved measurements of photoassisted electron emission showed that these possess the same response as the laser pulse with no discernible delay. These results indicate that the volcano device structure is effective at eliminating the generation of diffusion carriers and that a fully optimized FEA is promising as a photocathode for producing high-speed modulated electron beams. [ABSTRACT FROM AUTHOR]

Published

2016

2. Graphene-oxide-semiconductor planar-type electron emission device.

Author

Katsuhisa Murakami, Shunsuke Tanaka, Akira Miyashita, Masayoshi Nagao, Yoshihiro Nemoto, Masaki Takeguchi, and Jun-ichi Fujita

Subjects

*GRAPHENE oxide, *METAL oxide semiconductors, *ELECTRON emission, *CURRENT density (Electromagnetism), *ELECTRON scattering, *ELECTRIC conductivity

Abstract

Graphene was used as the topmost electrode for a metal-oxide-semiconductor planar-type electron emission device. With several various layers, graphene as a gate electrode on the thin oxide layer was directly deposited by gallium vapor-assisted chemical vapor deposition. The maximum efficiency of the electron emission, defined as the ratio of anode current to cathode current, showed no dependency on electrode thickness in the range from 1.8 nm to 7.0 nm, indicating that electron scattering on the inside of the graphene electrode is practically suppressed. In addition, a high emission current density of 1–100 mA/cm2 was obtained while maintaining a relatively high electron emission efficiency of 0.1%–1.0%. The graphene-oxide-semiconductor planar-type electron emission device has great potential to achieve both high electron emission efficiency and high electron emission current density in practical applications. [ABSTRACT FROM AUTHOR]

Published

2016