Your search keyword '"Hayato Saito"' showing total 2 results

1. Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation

Author

Tomoyuki Chigira, Naohiro Manago, Toshinori Hanyu, Hiroaki Kuze, Mineo Fukushima, Tatsuo Shiina, Hayato Saito, and Fumihiko Kanayama

Subjects

Chemistry, Scattering, Physics, QC1-999, Analytical chemistry, Alpha particle, Radius, Ion, symbols.namesake, Wavelength, Ionization, Phase (matter), symbols, Physics::Atomic Physics, Raman spectroscopy, Physics::Atmospheric and Oceanic Physics

Abstract

A compact Raman lidar has been developed for studying phase changes of water in the atmosphere under the influence of ionization radiation. The Raman lidar is operated at the wavelength of 349 nm and backscattered Raman signals of liquid and vapor phase water are detected at 396 and 400 nm, respectively. Alpha particles emitted from 241 Am of 9 MBq ionize air molecules in a scattering chamber, and the resulting ions lead to the formation of liquid water droplets. From the analysis of Raman signal intensities, it has been found that the increase in the liquid water Raman channel is approximately 3 times as much as the decrease in the vapor phase water Raman channel, which is consistent with the theoretical prediction based on the Raman cross-sections. In addition, the radius of the water droplet is estimated to be 0.2 μm.

Published

2016

2. COMPACT RAMAN LIDAR MEASUREMENT OF LIQUID AND VAPOR PHASE WATER UNDER THE INFLUENCE OF IONIZING RADIATION.

Author

Tatsuo Shiina, Tomoyuki Chigira, Hayato Saito, Naohiro Manago, Hiroaki Kuze, Toshinori Hanyu, Fumihiko Kanayama, and Mineo Fukushima

Subjects

LIDAR, ATMOSPHERIC water vapor, IONIZING radiation, BACKSCATTERING, WAVELENGTHS

Abstract

A compact Raman lidar has been developed for studying phase changes of water in the atmosphere under the influence of ionization radiation. The Raman lidar is operated at the wavelength of 349 nm and backscattered Raman signals of liquid and vapor phase water are detected at 396 and 400 nm, respectively. Alpha particles emitted from 241Am of 9 MBq ionize air molecules in a scattering chamber, and the resulting ions lead to the formation of liquid water droplets. From the analysis of Raman signal intensities, it has been found that the increase in the liquid water Raman channel is approximately 3 times as much as the decrease in the vapor phase water Raman channel, which is consistent with the theoretical prediction based on the Raman cross-sections. In addition, the radius of the water droplet is estimated to be 0.2 μm. [ABSTRACT FROM AUTHOR]

Published

2016