摘要
Recent research on TFTR has emphasized optimization of performance in deuterium plasmas, transport studies and studies of energetic ion and fusion product physics in preparation for the D-T experiments that will commence in July of 1993. TFTR has achieved full hardware design parameters, and the best TFTR discharges in deuterium are projected to QDT of 0.3 to 0.5. The physics phenomena that will be studied during the D-T phase will include: tritium particle confinement and fueling, ICRF heating with tritium, species scaling with tritium, collective alpha-particle instabilities, alpha heating of the plasma and helium ash buildup. It is important for the fusion program that these physics issues be addressed to identify regimes of benign alpha behavior, and to develop techniques to actively stabilize or control instabilities driven by collective alpha effects.
| 原文 | English |
|---|---|
| 頁(從 - 到) | 1324-1331 |
| 頁數 | 8 |
| 期刊 | Fusion Technology |
| 卷 | 21 |
| 發行號 | 3 pt 2A |
| 出版狀態 | Published - 1992 五月 1 |
| 事件 | Proceedings of the 10th Topical Meeting on the Technology of Fusion Energy - Boston, MA, USA 持續時間: 1992 六月 7 → 1992 六月 12 |
指紋
All Science Journal Classification (ASJC) codes
- Engineering(all)
引用此文
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Status and plans for TFTR. / Hawryluk, R. J.; Mueller, D.; Hosea, J.; Barnes, C. W.; Beer, M.; Bell, M. G.; Bell, R.; Biglari, H.; Bitter, M.; Boivin, R.; Bretz, N. L.; Budny, R.; Bush, C. E.; Chen, L.; Cheng, Chio-Zong; Cowley, S.
於: Fusion Technology, 卷 21, 編號 3 pt 2A, 01.05.1992, p. 1324-1331.研究成果: Conference article
TY - JOUR
T1 - Status and plans for TFTR
AU - Hawryluk, R. J.
AU - Mueller, D.
AU - Hosea, J.
AU - Barnes, C. W.
AU - Beer, M.
AU - Bell, M. G.
AU - Bell, R.
AU - Biglari, H.
AU - Bitter, M.
AU - Boivin, R.
AU - Bretz, N. L.
AU - Budny, R.
AU - Bush, C. E.
AU - Chen, L.
AU - Cheng, Chio-Zong
AU - Cowley, S.
PY - 1992/5/1
Y1 - 1992/5/1
N2 - Recent research on TFTR has emphasized optimization of performance in deuterium plasmas, transport studies and studies of energetic ion and fusion product physics in preparation for the D-T experiments that will commence in July of 1993. TFTR has achieved full hardware design parameters, and the best TFTR discharges in deuterium are projected to QDT of 0.3 to 0.5. The physics phenomena that will be studied during the D-T phase will include: tritium particle confinement and fueling, ICRF heating with tritium, species scaling with tritium, collective alpha-particle instabilities, alpha heating of the plasma and helium ash buildup. It is important for the fusion program that these physics issues be addressed to identify regimes of benign alpha behavior, and to develop techniques to actively stabilize or control instabilities driven by collective alpha effects.
AB - Recent research on TFTR has emphasized optimization of performance in deuterium plasmas, transport studies and studies of energetic ion and fusion product physics in preparation for the D-T experiments that will commence in July of 1993. TFTR has achieved full hardware design parameters, and the best TFTR discharges in deuterium are projected to QDT of 0.3 to 0.5. The physics phenomena that will be studied during the D-T phase will include: tritium particle confinement and fueling, ICRF heating with tritium, species scaling with tritium, collective alpha-particle instabilities, alpha heating of the plasma and helium ash buildup. It is important for the fusion program that these physics issues be addressed to identify regimes of benign alpha behavior, and to develop techniques to actively stabilize or control instabilities driven by collective alpha effects.
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M3 - Conference article
AN - SCOPUS:0026855638
VL - 21
SP - 1324
EP - 1331
JO - Fusion Science and Technology
JF - Fusion Science and Technology
SN - 1536-1055
IS - 3 pt 2A
ER -