Spatiotemporal characterization of zonal flows with multi-channel correlation Doppler reflectometers in the HL-2A Tokamak

W.L. Zhong; Z.B. Shi; Y. Xu; X.L. Zou; X.R. Duan; W. Chen; M. Jiang; Z.C. Yang; B.Y. Zhang; P.W. Shi; Z.T. Liu; M. Xu; X.M. Song; J. Cheng; R. Ke; L. Nie; Z.Y. Cui; B.Z. Fu; X.T. Ding; J.Q. Dong; Yi Liu; L.W. Yan; Q.W. Yang; Y. Liu

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Spatiotemporal characterization of zonal flows with multi-channel correlation Doppler reflectometers in the HL-2A Tokamak

机译：HL-2A托卡马克中多通道相关多普勒反射计对地层流的时空特征

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The oscillations of poloidal plasma flows induced by radially sheared zonal flows are investigated by newly developed correlation Doppler reflectometers in the HL-2A tokamak. The non-disturbing diagnostic allows one to routinely measure the rotation velocity of turbulence, and hence the radial electric field fluctuations. With correlation Doppler reflectometers, a three-dimensional spatial structure of geodesic acoustic mode (GAM) is surveyed, including the symmetric feature of poloidal and toroidal E_r fluctuations, the dependence of GAM frequency on radial temperature and the radial propagation of GAMs. The co-existence of low-frequency zonal flow and GAM is presented. The temporal behaviors of GAM during ramp-up experiments of plasma current and electron density are studied, which reveal the underlying damping mechanisms for the GAM oscillation level.

机译：通过新开发的相关多普勒反射仪在HL-2A托卡马克中研究了径向剪切的纬向流引起的极向等离子体流的振荡。不受干扰的诊断允许人们常规地测量湍流的旋转速度，从而测量径向电场的波动。利用相关的多普勒反射计，研究了测地声模（GAM）的三维空间结构，包括极化和环形E_r涨落的对称特征，GAM频率对径向温度的依赖性以及GAM的径向传播。提出了低频纬向流与GAM的共存。研究了等离子体电流和电子密度的加速实验期间GAM的时间行为，揭示了GAM振荡水平的潜在阻尼机制。

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来源
《Nuclear fusion》 |2015年第11期|113005.1-113005.10|共10页
作者
W.L. Zhong; Z.B. Shi; Y. Xu; X.L. Zou; X.R. Duan; W. Chen; M. Jiang; Z.C. Yang; B.Y. Zhang; P.W. Shi; Z.T. Liu; M. Xu; X.M. Song; J. Cheng; R. Ke; L. Nie; Z.Y. Cui; B.Z. Fu; X.T. Ding; J.Q. Dong; Yi Liu; L.W. Yan; Q.W. Yang; Y. Liu;
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作者单位

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

CEA, IRFM, F-13108 Saint-Paul-lez-Durance, France;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

School of Physics and Chemistry, Xihua University, Chengdu 610039, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China ,Institute for Fusion Theory and Simulation, Zhejiang University, Hangzhou 310027, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

Southwestern Institute of Physics, PO Box 432, Chengdu 610041, People's Republic of China;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);
原文格式 PDF
正文语种 eng
中图分类
关键词
turbulence; zonal flows; Doppler reflectometry; long-range correlation;

机译：湍流地带流量多普勒反射法;远距离相关;
入库时间 2022-08-18 00:42:32

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1. Characterizations of Low-Frequency Zonal Flow in the Edge Plasma of the HL-2A Tokamak [J] . A.D. Liu, T. Lan, C.X. Yu, Physical review letters . 2009,第9期

机译：HL-2A托卡马克边缘等离子体中的低频区流特征
2. Measurement of turbulence propagation velocity using Doppler reflectometer on HL-2A tokamak [J] . Xiao WW, Ding XT, Liu ZT, Plasma Science & Technology . 2008,第4期

机译：使用HL-2A托卡马克多普勒反射仪测量湍流传播速度
3. Measurement of Turbulence Propagation Velocity Using Doppler Reflectometer on HL-2A Tokamak [J] . 肖维文, 丁玄同, 刘泽田, 等离子体科学和技术：英文版 . 2008,第004期

机译：用HL-2A托卡马克多普勒反射计测量湍流传播速度。
4. Overview of recent results on long-range correlations and zonal flows in the edge of TEXTOR tokamak [C] . Y. Xu, I. Shesterikov, M. Van Schoor, Conference on Plasma Physics . 2011

机译：近期结果概述了托卡纳克边缘的远程相关性和区域流动
5. Measurement of velocity turbulence and application to zonal flow detection in tokamak plasmas. [D] . Jakubowski, Marcin. 2003

机译：速度湍流的测量及其在托卡马克等离子体中的纬向流检测中的应用。
6. Evaluation of fetal foramen ovale blood flow by pulsed Doppler ultrasonography combined with spatiotemporal image correlation: [O] . Wenjuan Tang, Yuanchen Luo, Shi Zeng, 2021

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7. Experimental Study of Turbulence and Zonal Flow in Edge Plasmas of the HL-2A Tokamak [O] . Jiaqi DONG, Kaijun ZHAO, Longwen YAN, 2010

机译：HL-2A Tokamak边缘等离子体中湍流和区流动的实验研究

Spatiotemporal characterization of zonal flows with multi-channel correlation Doppler reflectometers in the HL-2A Tokamak

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