ICRF heating scenarios for the IGNITOR machine

被引:4
|
作者
Riccitelli, M
Vecchi, G
Maggiora, R
Phillips, CK
Majeski, RP
Wilson, JR
Smithe, DN
机构
[1] Politecn Torino, Dipartimento Elettron, I-10129 Turin, Italy
[2] Princeton Univ, Princeton Plasma Phys Lab, Princeton, NJ 08543 USA
[3] Mission Res Co, Newington, VA USA
来源
FUSION ENGINEERING AND DESIGN | 1999年 / 45卷 / 01期
关键词
IGNITOR; ICRF; heating scenarios; minority heating; first harmonic heating;
D O I
10.1016/S0920-3796(98)00424-4
中图分类号
TL [原子能技术]; O571 [原子核物理学];
学科分类号
0827 ; 082701 ;
摘要
A large frequency range ICRF antenna (70 < f < 140 MHz) is proposed for the IGNITOR machine, in order to allow either hydrogen or helium-3 minority heating for all the planned operating scenarios. Results from a feasibility study for such a heating system are presented. The power absorbed by the different plasma species as a function of plasma parameters for different heating scenarios was calculated using both 1-dimensional and 2-dimensional kinetic wave codes. Different alternatives are proposed in order to improve heating performances while accounting for the effects of collisional redistribution of the absorbed power. Wave absorption is predicted to be very strong for a number of different RF scenarios. Single pass absorption by alpha particles, as given by a 1-dimensional integral kinetic wave code, is also discussed. (C) 1999 Elsevier Science S.A. All rights reserved.
引用
收藏
页码:1 / 13
页数:13
相关论文
共 50 条
  • [41] SNARF analysis of ICRF heating on TFTR
    Smithe, D.N.
    Phillips, C.K.
    Hammett, G.W.
    Colestock, P.L.
    AIP Conference Proceedings, 1989, 190
  • [42] Effects of beam energy spread on the Weibel instability in fast ignitor scenarios
    Cai, HB
    Zhu, SP
    Zheng, CY
    He, XT
    Li, JW
    CHINESE PHYSICS LETTERS, 2006, 23 (01) : 161 - 164
  • [43] Real-time capable modeling of ICRF heating on NSTX and WEST via machine learning approaches
    Sanchez-Villar, A.
    Bai, Z.
    Bertelli, N.
    Bethel, E. W.
    Hillairet, J.
    Perciano, T.
    Shiraiwa, S.
    Wallace, G. M.
    Wright, J. C.
    NUCLEAR FUSION, 2024, 64 (09)
  • [44] High power ICRF heating experiment in LHD
    Seki, T
    Kumazawa, R
    Mutoh, T
    Watari, T
    Shimpo, F
    Nomura, G
    Kato, A
    Yokota, M
    Saito, K
    Torii, Y
    Yamamoto, T
    Takeuchi, N
    Cheng, Z
    RADIO FREQUENCY POWER IN PLASMAS, 2001, 595 : 67 - 74
  • [45] Current Status of ICRF Heating Experiments on EAST
    张新军
    赵燕平
    毛玉周
    袁帅
    薛迪冶
    汪磊
    丁家义
    秦成明
    琚松青
    程艳
    王成浩
    沈俊松
    宋云涛
    林毅君
    Plasma Science and Technology, 2011, (02) : 172 - 174
  • [46] PONDEROMOTIVE STABILIZATION OF INTERCHANGE MODES AT ICRF HEATING
    KOTELNIKOV, IA
    YAKOVCHENKO, SG
    PLASMA PHYSICS AND CONTROLLED FUSION, 1994, 36 (05) : 797 - 806
  • [47] ICRF heating and current drive experiments on TFTR
    Rogers, JH
    Hosea, JC
    LeBlanc, B
    Majeski, R
    Phillips, CK
    Schilling, G
    Wilson, JR
    Batha, SH
    Bell, MG
    Darrow, DS
    Duong, HH
    Hill, KW
    Levinton, FM
    Medley, SS
    Petrov, MP
    Synakowski, EJ
    Taylor, G
    Zarnstorff, MC
    Zweben, SJ
    FUSION ENERGY 1996, VOL 3, 1997, : 317 - 326
  • [48] SUMMARY OF ICRF HEATING IN THE MACROTOR AND MICROTOR TOKAMAKS
    TAYLOR, RJ
    MORALES, GJ
    TALMADGE, S
    ZWEBEN, SJ
    BULLETIN OF THE AMERICAN PHYSICAL SOCIETY, 1980, 25 (08): : 905 - 906
  • [49] ENHANCEMENT OF THE REACTION-RATE BY ICRF HEATING
    KRAPCHEV, VB
    NUCLEAR FUSION, 1985, 25 (04) : 455 - 461
  • [50] Bulk Ion Heating with ICRF Waves in Tokamaks
    Mantsinen, M. J.
    Bilato, R.
    Bobkov, V. V.
    Kappatou, A.
    McDermott, R. M.
    Nocente, M.
    Odstrcil, T.
    Tardini, G.
    Bernert, M.
    Dux, R.
    Hellsten, T.
    Mantica, P.
    Maraschek, M.
    Nielsen, S. K.
    Noterdaeme, J-M.
    Rasmussen, J.
    Ryter, F.
    Stejner, M.
    Stober, J.
    Tardocchi, M.
    RADIOFREQUENCY POWER IN PLASMAS, 2015, 1689
12345