Alumina reduction by laser sustained plasma for aluminum-based renewable energy cycling

Alumina reduction by laser sustained plasma for aluminum-based renewable energy cycling

A novel alumina (Al2O3) reduction technique for a renewable energy cycling system based on aluminum is proposed. Al2O3 powder was fed into laser-sustained plasma and thermally dissociated. The produced Al was expanded to supersonic speeds through a nozzle. From the Al and argon line distributions in...

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Veröffentlicht in:Journal of renewable and sustainable energy 2013-05, Vol.5 (3)
Hauptverfasser: Matsui, Makoto, Fukuji, Naohiro, Nakano, Masakatsu, Komurasaki, Kimiya, Arakawa, Yoshihiro, Goto, Tetsuya, Shirakata, Hirofumi
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container_issue 3
container_start_page
container_title Journal of renewable and sustainable energy
container_volume 5
creator Matsui, Makoto
Fukuji, Naohiro
Nakano, Masakatsu
Komurasaki, Kimiya
Arakawa, Yoshihiro
Goto, Tetsuya
Shirakata, Hirofumi
description A novel alumina (Al2O3) reduction technique for a renewable energy cycling system based on aluminum is proposed. Al2O3 powder was fed into laser-sustained plasma and thermally dissociated. The produced Al was expanded to supersonic speeds through a nozzle. From the Al and argon line distributions in the flow direction, it was found that Al remained in the dissociated state. A water-cooled copper tube was inserted in the flow to collect Al. X-ray analysis indicated that elemental Al was observed on the surface of the tube. The maximum value of the estimated reduction efficiency was 5%.
doi_str_mv 10.1063/1.4807607
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title Alumina reduction by laser sustained plasma for aluminum-based renewable energy cycling
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