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

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

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, respecti...

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Main Authors: Shiina Tatsuo, Chigira Tomoyuki, Saito Hayato, Manago Naohiro, Kuze Hiroaki, Hanyu Toshinori, Kanayama Fumihiko, Fukushima Mineo
Format: Article
Language:English
Published: EDP Sciences 2016-01-01
Series:EPJ Web of Conferences
Online Access:http://dx.doi.org/10.1051/epjconf/201611925012
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spelling doaj-042fc8c7924245b69005d97448ecc6922021-08-02T07:28:51ZengEDP SciencesEPJ Web of Conferences2100-014X2016-01-011192501210.1051/epjconf/201611925012epjconf_ilrc2016_25012Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing RadiationShiina Tatsuo0Chigira Tomoyuki1Saito Hayato2Manago Naohiro3Kuze Hiroaki4Hanyu Toshinori5Kanayama Fumihiko6Fukushima Mineo7Graduate School of Advanced Integration Science, Chiba UniversityGraduate School of Advanced Integration Science, Chiba UniversityCenter for Environmental Remote Sensing, Chiba UniversityCenter for Environmental Remote Sensing, Chiba UniversityCenter for Environmental Remote Sensing, Chiba UniversityJapan Atomic Energy AgencyJapan Atomic Energy AgencyJapan Atomic Energy AgencyA 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.http://dx.doi.org/10.1051/epjconf/201611925012
collection DOAJ
language English
format Article
sources DOAJ
author Shiina Tatsuo
Chigira Tomoyuki
Saito Hayato
Manago Naohiro
Kuze Hiroaki
Hanyu Toshinori
Kanayama Fumihiko
Fukushima Mineo
spellingShingle Shiina Tatsuo
Chigira Tomoyuki
Saito Hayato
Manago Naohiro
Kuze Hiroaki
Hanyu Toshinori
Kanayama Fumihiko
Fukushima Mineo
Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation
EPJ Web of Conferences
author_facet Shiina Tatsuo
Chigira Tomoyuki
Saito Hayato
Manago Naohiro
Kuze Hiroaki
Hanyu Toshinori
Kanayama Fumihiko
Fukushima Mineo
author_sort Shiina Tatsuo
title Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation
title_short Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation
title_full Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation
title_fullStr Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation
title_full_unstemmed Compact Raman Lidar Measurement of Liquid and Vapor Phase Water Under the Influence of Ionizing Radiation
title_sort compact raman lidar measurement of liquid and vapor phase water under the influence of ionizing radiation
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2016-01-01
description 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.
url http://dx.doi.org/10.1051/epjconf/201611925012
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AT chigiratomoyuki compactramanlidarmeasurementofliquidandvaporphasewaterundertheinfluenceofionizingradiation
AT saitohayato compactramanlidarmeasurementofliquidandvaporphasewaterundertheinfluenceofionizingradiation
AT managonaohiro compactramanlidarmeasurementofliquidandvaporphasewaterundertheinfluenceofionizingradiation
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AT kanayamafumihiko compactramanlidarmeasurementofliquidandvaporphasewaterundertheinfluenceofionizingradiation
AT fukushimamineo compactramanlidarmeasurementofliquidandvaporphasewaterundertheinfluenceofionizingradiation
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