<RESEARCH REPORT>D-^3He FUELS IN A FIELD-REVERSED CONFIGURATION
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概要
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Favorable features of the D-^3He fuel cycle in a field-reversed configuration are described. Based on a theoretical analysis, one find that the estimated plant efficiency is more than 70% and the 14 MeV neutron power fraction is as small as 1%. To reach the D-^3He innition temperature of 100 keV with a reasonable external power source, one can first ignite a D-T configuration and then alter the fuel to D-^3He. Heating of the plasma is attributed to energetic fusion charged particles and no additional heating is neccessary. The equilibria of D-^3He ignited plasmas may be self-sustained due to the preferential trapping of fusion protons in a field-reversed configuration.
- 核融合科学研究所の論文
著者
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Ohnishi Masami
Kyoto University
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Ohnishi Masami
Institute Of Atomic Energy Kyoto University
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OKAMOTO Masao
Research Information Center, Institute of Plasma Physics, Nagoya University
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BERK HERBERT
Institute for Fusion Studies, University of Texas at Austin
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TAJIMA TOSHIKI
Institute for Fusion Studies, University of Texas at Austin
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Nomura Yasuyuki
Research Information Center Institute Of Plasma Physics Nagoya University
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Okamoto Masao
Research Information Center Institute Of Plasma Physics Nagoya University
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Tajima Toshiki
Institute For Fusion Studies University Of Texas At Austin
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MOMOTA Hiromu
Research Information Center, Institute of Plasma Physics, Nagoya University
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Momota Hiromu
Research Information Center Institute Of Plasma Physics Nagoya University
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Berk Herbert
Institute For Fusion Studies University Of Texas At Austin
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