Study on Chemical Reactivity Control of Sodium by Suspended Nanoparticles II
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概要
- 論文の詳細を見る
A study was conducted on the control of the chemical reactivity of sodium utilizing the atomic interaction between sodium and nanoparticles. The authors reported in a previous paper that the atomic interaction between sodium and nanoparticles increases and has the potential to suppress chemical reactivity. In this paper, the authors examined the released reaction heat and reaction behavior. As a result, it was confirmed that the released reaction heat and reaction rate decreased. From the results of experimental studies, it is clear that the suppression of chemical reactivity is caused by changes in sodium evaporation rate and fundamental physical properties such as surface tension, which originate from the change in the atomic interaction between sodium and nanoparticle atoms. The suppression of chemical reactivity applied to an FBR coolant was estimated for the cases of sodium combustion and sodium-water reaction. It was confirmed that the concept of suspending nanoparticles into sodium has a high potential for the suppression of chemical reactivity. The applicability as coolant to the FBR was investigated, including not only the chemical reaction properties but also the aspects of heat transfer and operation.
- 社団法人 日本原子力学会の論文
著者
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SUGIYAMA Ken-ichiro
Hokkaido University
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ARA Kuniaki
Japan Atomic Energy Agency
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Kitagawa Hiroshi
Kyushu University, Faculty of Science
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NAGAI Masahiko
Mitsubishi Heavy Industries, Ltd., Technical Headquarters, Nagasaki Research & Development Center
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YOSHIOKA Naoki
Mitsubishi FBR Systems, Inc.
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