托卡马克中ECW对LHW耦合特性的影响研究

黄捷; 白兴宇; 曾浩; 唐昌建

doi:10.7498/aps.62.025202

摘要

托卡马克中电子回旋波(ECW)与低杂波(LHW)协同作用的实验发现, 在LHW维持的等离子体中注入ECW将引起LHW 反射系数的减小. 本中从理论上研究了LHW的耦合特性与天线口等离子体密度的关系, 以及ECW注入后使得等离子体密度从芯部向边缘输运的pump-out现象. 通过本文的研究, 给出了pump-out现象的基本规律, 证实了ECW所致的pump-out使得LHW天线口的等离子体密度有所提高, 从而改善了LHW的耦合. 这一结论得到了相关实验的支持. 研究还指出, 在双波协同驱动实验的研究中, 由于ECW的pump-out导致边缘密度发生改变时, 当对协同净增电流进行修正.

关键词:

Abstract

It is found in the experiments on synergy between low hybrid wave (LHW) and electron cyclotron wave (ECW) that the LHW reflection coefficient decreases with the injection of ECW into plasmas in the presence of LHW. In the present paper, the coupling characteristics of LHW, and the pump-out phenomenon caused by ECW are analyzed theoretically. The analysis shows the law of pump-out and the increase of plasma density in the vicinity of the grill mouth caused by pump-out, there by improving LHW coupling. The conclusion is proved by the experiments. Also, considering the change of the plasma density in the vicinity of the grill mouth caused by pump-out in synergy experiments, the synergy current should be corrected.

Keywords:

LHW coupling /
synergy effect /
TEM /
pump-out

作者及机构信息

1.
四川大学物理科学与技术学院, 成都 610065;

2.
核工业西南物理研究院, 成都 610041

基金项目: ITER计划专项国内配套研究(批准号: 2009GB105003, 2010GB107003)资助的课题.

Authors and contacts

1.
Physics Department of Sichuan university 610064, China;

2.
Southwestern Institute of Physics 610041, China

Funds: Project supported by the National Magnetic Confinement Fusion Science Program, China (Grant Nos. 2009GB105003, 2010GB107003).

参考文献

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[23]	Tokar Z, 1994 Plasma Phys. Control. Fusion 36 1819
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[26]	Becker G 2004 Nucl. Fusion 44 933
[27]	G～ rmezano C, Morea D 1984 Plasma Phys. Control. Fusion 26 553
[28]	Mlynek A, Reich M, Giannone L, Treutterer W, Behler K, Blank H, Buhler A, Cole R, Eixenberger H, Fischer R, Lohs A, L uddecke K, Merkel R, Neu G, Ryter F, Zasche D, the ASDEX Upgrade Team 2011 Nucl. Fusion 51 043002
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施引文献

[1]	Brambilla M, 1976 Nucl. Fusion 16 1
[2]	Stevens J, Ono M, Horton R, Wilson J R 1981 Nucl. Fusion 21 1259
[3]	Ma Z F, Li D F, Chen J 1982 Acta Phys. Sin. 31 159 (in Chinese) [马中芳, 李大丰, 陈激 1982 31 159]
[4]	Petrzilka V A, Leuterer F, Soldner F X, Giannone L, Schubert R 1991 Nucl. Fusion 31 1758
[5]	Pericoli Ridolfini V, Ekedahl A, SKErents, Mailloux J, Podda S, Sarazin Y, Tuccillo A A 2004 Plasma Phys. Control. Fusion 46 349
[6]	Ekedahl A, Rantamaki K, Goniche M, Mailloux J, Petrzilka V, Alper B, Baranov Y, Basiuk V, Beaumont P, Corrigan G, Delpech L, Erents K, Granucci G, Hawkes N, Hobirk J, Imbeaux F, Joffrin E, Kirov K, Loarer T, McDonald D, Nave M F F, Nunes I, Ongena J, Parail V, Piccolo F, Rachlew E, Silva C, Sirinelli A, Stamp M, Zastrow K D, JET-EFDA contributors 2009 Plasma Phys. Control. Fusion 51 044001
[7]	Ding B J, Li M H, Qin Y L, Li W K, Zhang L Z, Shan J F, Liu F K, Wang M, Meng L G, Xu H D, Wang D X, Jie Y X, Sun Y W, Shen B, Zhang W, Wang X M, Wu J H, Gao X, Zhang X D, Zhao Y P, HT-7 Team 2010 Phys. Plasmas 17 022504
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[9]	Yamamoto T, Hoshino K, Kawashima H, Uesugi Y, Mori M, Suzuki N, Ohta K, Matoba T, Kasai S, Kawakami T, Maeno M, Matsuda T, Matsumoto H, Miura Y, Ochiai I, Odajima K, Ogawa T, Ogawa H, Ohtsuka H, Sengoku S, Shoji T, Tamai H, Tanaka Y, Yamamoto S, Yamauchi T, Yanagisawa I 1987 Phys. Rev. Lett. 58, 2220
[10]	Maekawa T, Maehara T, Minami T, Kishigami Y, Kishino T, Makino K, Hanada K, Nakamura M, Terumichi Y, Tanaka S 1993 Phys. Rev. Lett. 70 2561
[11]	Giruzzi G, Artaud J F, Dumont R J, Imbeaux F, Bibet P, Berger-By G, Bouquey F, Clary J, Darbos C, Ekedahl A, Hoang G T, Lennholm M, Maget P, Magne R, Ségui J L 2004 Phys. Rev. Lett. 93 255002
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[13]	Gilgenbach R M, Read M E, Hackett K E, Lucey R, Hui B, Granatstein V L, Chu K R, England A C, Loring C M, Eldridge O C, Howe H C, Kulchar A G, Lazarus E, Murakami M, Wilgen J B 1980 Phys. Rev. Lett. 44 647
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[15]	Zabolotsky A, Weisen H, Team TCV 2006 Plasma Phys. Control. Fusion 48 369
[16]	Gohil P, Evans T E, Ferron J R, Moyer R A, Petty C C, Burrell K H, Casper T A, Garofalo A M, Hyatt A W, Jayakumar R J, Kessel C, Kim J Y, La Haye R J, Lohr J, Luce T C, Makowski M A, Mazon D, Menard J, Murakami M, Politzer P A, Prater R, Wade M R 2006 Plasma Phys. Control. Fusion 48 A45
[17]	Mlynek A, Reich M, Giannone L, Treutterer W, Behler K, Blank H, Buhler A, Cole R, Eixenberger H, Fischer R, Lohs A, Lddecke K, Merkel R, Neu G, Ryter F, Zasche D, the ASDEX Upgrade Team 2011 Nucl. Fusion 51 043002
[18]	Yan L W, Duan X R, Ding X T, Dong J Q, Yang Q W, Liu Y, Zou X L, Liu D Q, Xuan W M, Chen L Y, Rao J, Song X M, Huang Y, Mao W C, Wang Q M, Li Q, Cao Z, Li B, Cao J Y, Lei G J, Zhang J H, Li X D, Chen W, Cheng J, Cui C H, Cui Z Y, Deng Z C, Dong Y B, Feng B B, Gao Q D, Han X Y, Hong W Y, Huang M, Ji X Q, Kang Z H, Kong D F, Lan T, Li G S, Li H J, Li Q, Li W, Li Y G, Liu A D, Liu Z T, Luo C W, Mao X H, Pan Y D, Peng J F, Shi Z B, Song S D, Song X Y, Sun H J, Wang A K, Wang M X, Wang Y Q, Xiao W W, Xie Y F, Yao L H, Yao L Y, Yu D L, Yuan B S, Zhao K J, Zhong G W, Zhou J, Zhou Y, Yan J C, Yu C X, Pan C H, Liu Y, the HL-2A team 2011 Nucl. Fusion 51 094016
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[22]	Xiao W W, Zou X L, Ding X T, Yao L H, Feng B B, Song X M, Song S D, Zhou Y, Liu Z T, Yuan B S, Sun H J, Ji X Q, Gao Y D, Li Y G, Yan L W, Yang Q W, Liu Y, Dong J Q, Duan X R, Liu Y, Pan C H, HL-2A Team 2010 Phys. Rev. Lett. 104 215001
[23]	Tokar Z, 1994 Plasma Phys. Control. Fusion 36 1819
[24]	Kalupin D, Tokar M Z, Unterberg B, Loozen X, Pilipenko D 2005 Nucl. Fusion 45 468
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[27]	G～ rmezano C, Morea D 1984 Plasma Phys. Control. Fusion 26 553
[28]	Mlynek A, Reich M, Giannone L, Treutterer W, Behler K, Blank H, Buhler A, Cole R, Eixenberger H, Fischer R, Lohs A, L uddecke K, Merkel R, Neu G, Ryter F, Zasche D, the ASDEX Upgrade Team 2011 Nucl. Fusion 51 043002
[29]	Hong B B, Chen S Y, Tang C J, Zhang X J, Hu Y J 2012 Acta Phys. Sin. 61 115207 (in Chinese) [洪斌斌, 陈少永, 唐昌建, 张新军, 胡有俊 2012 61 115206]

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