IMPROVEMENT OF PLASMA CORE CONFINEMENT VIA ELECTRON-ROOT REALIZATION BY STRONGLY FOCUSED ECRH IN LHD: CORE ELECTRON-ROOT CONFINEMENT

T. SHIMOZUMA; M. YOKOYAMA; K. IDA; Y. TAKEIRI; S. KUBO; S. MURAKAMI; A. WAKASA; H. IDEI; Y. YOSHIMURA; T. NOTAKE; S. INAGAKI; N. TAMURA; K. TOI; N. OHYABU; M. OSAKABE; K. IKEDA; K. TSUMORI; Y. OKA; K. NAGAOKA; O. KANEKO; I. YAMADA; K. NARIHARA; Y. NAGAYAMA; S. MUTO; K. TANAKA; T. TOKUZAWA; S. MORITA; M. GOTO; M. YOSHINUMA; H. FUNABA; T. MORISAKI; K. Y. WATANABE; J. MIYAZAWA; T. MUTOH; T. WATARI; K. OHKUBO

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IMPROVEMENT OF PLASMA CORE CONFINEMENT VIA ELECTRON-ROOT REALIZATION BY STRONGLY FOCUSED ECRH IN LHD: CORE ELECTRON-ROOT CONFINEMENT

机译：通过强烈聚焦ECRH通过电子根实现对等离子体核心约束的改进：核心电子根约束

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Core electron-root confinement (CERC), observed in the Large Helical Device as well as in other helical devices, is an improved electron energy confinement mode. It is characterized by a highly peaked electron temperature profile in the core region and appears when the centrally focused electron cyclotron resonance heating power exceeds a certain threshold value. This threshold value has been clarified to associate with the transition of the radial electric field (E_r) from the ion root (small negative value) to the electron root (large positive value greater than a few kV/m), based on the bifurcation nature of E_r due to the ambipolarity condition of neoclassical transport fluxes that is specific in nonaxisymmetric configurations. It has been experimentally recognized that a steeper T_e gradient is realizedrnwith a clear transition (power threshold nature) in target plasmas with counter neutral beam injection (NBI) than ones with codirectional NBI. It has been interpreted, based on the heat pulse propagation experiment, to be related to the rational surface or the island induced by the NBI-driven current. Transport analyses have shown that the incremental thermal diffusivity of electron heat transport becomes lower, and the standard thermal diffusivity decreases with the increase of heating power in CERC plasmas.

机译：在大型螺旋装置以及其他螺旋装置中观察到的芯电子根限制（CERC）是一种改进的电子能量限制模式。它的特征是在核心区域出现高度峰值的电子温度曲线，并在集中聚焦的电子回旋共振能量超过某个阈值时出现。根据分叉性质，已明确此阈值与径向电场（E_r）从离子根（较小的负值）到电子根（较大的正值（大于几kV / m））的过渡相关由于在非轴对称配置中特定的新古典输运通量的双极性条件，导致E_r的变化。实验已经认识到，与同向NBI相比，在具有反向中性束注入（NBI）的目标等离子体中，具有清晰的跃迁（功率阈值性质），实现了更陡的T_e梯度。根据热脉冲传播实验，它被解释为与由NBI驱动的电流感应的合理表面或孤岛有关。传输分析表明，电子热传输的增量热扩散率变小，并且标准热扩散率随着CERC等离子体中加热功率的增加而降低。

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来源
《Fusion Science and Technology》 |2010年第1期|P.38-45|共8页
作者
T. SHIMOZUMA; M. YOKOYAMA; K. IDA; Y. TAKEIRI; S. KUBO; S. MURAKAMI; A. WAKASA; H. IDEI; Y. YOSHIMURA; T. NOTAKE; S. INAGAKI; N. TAMURA; K. TOI; N. OHYABU; M. OSAKABE; K. IKEDA; K. TSUMORI; Y. OKA; K. NAGAOKA; O. KANEKO; I. YAMADA; K. NARIHARA; Y. NAGAYAMA; S. MUTO; K. TANAKA; T. TOKUZAWA; S. MORITA; M. GOTO; M. YOSHINUMA; H. FUNABA; T. MORISAKI; K. Y. WATANABE; J. MIYAZAWA; T. MUTOH; T. WATARI; K. OHKUBO;
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作者单位

National Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

Kyoto University, Department of Nuclear Engineering, Kyoto 606-8501, Japan;

rnKyoto University, Department of Nuclear Engineering, Kyoto 606-8501, Japan;

Research Institute for Applied Mechanics, Kyushu University, Kasuga 816-8580, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

RIKEN, Tera-Photonics Laboratory, Aoba Sendai-City, Miyagi 980-0845, Japan;

rnResearch Institute for Applied Mechanics, Kyushu University, Kasuga 816-8580, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

rnNational Institute for Fusion Science, Toki 509-5292, Japan;

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原文格式 PDF
正文语种 eng
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关键词
core electron-root confinement (CERC); electron heat transport; ECRH;

机译：核心电子根限制（CERC）;电子传热;ECRH;

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外文文献
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专利

1. Radial Electric Field Formation Including Electron Radial Drift for a Core Electron-Root Confinement (CERC) Plasma in LHD [J] . Seikichi MATSUOKA, Shinsuke SATAKE, Masayuki YOKOYAMA, Plasma and Fusion Research . 2011,第6期

机译：LHD核心电子根约束（CERC）等离子体的包括电子径向漂移在内的径向电场形成
2. COMMON FEATURES OF CORE ELECTRON-ROOT CONFINEMENT IN HELICAL DEVICES [J] . M. YOKOYAMA, H. MAASSBERG, C. D. BEIDLER, Fusion Science and Technology . 2006,第3期

机译：螺旋装置中核心电子根约束的共同特征
3. Core plasma confinement during detachment transition with RMP application in LHD [J] . M. Kobayashi, S. Masuzaki, K. Tanaka, Nuclear Materials and Energy . 2018,第3期

机译：RMP在LHD中的分离过渡过程中的核心血浆封闭
4. Progress of ECRH by EBW in over-dense plasmas and controlling the confinement regime by ECCD with high power launching in LHD [C] . H. Igami, Y. Yoshimura, H. Takahashi, Joint Workshop on Electron Cyclotron Emission and Electron Cyclotron Resonance Heating . 2014

机译：ECRH在过度等离子体中ECRH进展，并在LHD中推出高功率推出的欧洲经济委员会控制监禁制度
5. Spectroscopic determination of temperature and density spatial profiles and mix in inertial confinement fusion implosion cores. [D] . Welser, Leslie A. 2006

机译：用光谱法确定温度和密度的空间分布并在惯性约束聚变内爆内芯中混合。
6. Influence of the spatial confinement on the self-focusing of ultrashort pulses in hollow-core fibers [O] . Aurora Crego, Enrique Conejero Jarque, Julio San Roman -1

机译：空间限制对空心光纤中超短脉冲自聚焦的影响
7. Improvement of Ion Confinement in Core Electron-Root Confinement (CERC) Plasmas in Large Helical Device [O] . Yasuhiko TAKEIRI, Masayuki YOKOYAMA, Kenichi NAGAOKA, 2008

机译：大型螺旋装置中核心电子根限制（CERC）等离子体中离子限制的改进

IMPROVEMENT OF PLASMA CORE CONFINEMENT VIA ELECTRON-ROOT REALIZATION BY STRONGLY FOCUSED ECRH IN LHD: CORE ELECTRON-ROOT CONFINEMENT

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