Gyrotron Collective Thomson Scattering Diagnostics of Fast Ions in Textor and Asdex Upgrade

2007 IEEE 34th International Conference on Plasma Science (ICOPS) Pub Date : 2007-06-17 DOI:10.1109/PPPS.2007.4345610

P. Woskov, S. Korsholm, H. Bindslev, F. Leipold, F. Meo, P. Michelsen, S. Michelsen, S. Nielsen, E. Westerhof, J. Oosterbeek, J. Hoekzema, F. Leuterer, D. Wagner

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Abstract

Summary form only given. A critical need exists for confined fast ion diagnostics in tokamak fusion experiments, particularly for fusion product alpha particles in ITER and future fusion burning experiments. To develop this diagnostic capability and in support of current fast ion plasma physics research, collective Thomson scattering (CTS) diagnostics have been implemented at TEXTOR and ASDEX Upgrade (AUG) tokamaks using available gyrotron infrastructure with the addition of sensitive scattered signal receiver systems. At TEXTOR a 180 kW, 110 GHz gyrotron and a 42 channel. 6 GHz bandwidth heterodyne receiver has achieved up to 100 CTS scattered spectra per plasma shot with 4 ms time and 10 cm spatial resolution. Large scattering angles (~160deg) with steerable optics enable observation of fast ion spatial and field orientation anisotropies. Studies of fast ion dynamics behavior with neutral beam injection (NBI) and ion cyclotron heating have commenced, resulting in unique observations of fast ions redistributions during sawteeth and slow down after NBI turn off. At AUG a 1 MW, 105 GHz mode of a two-frequency gyrotron with a 50 channel, 10 GHz bandwidth receiver is becoming operational for CTS diagnostics with resolutions similar to TEXTOR. Precise gyrotron frequency measurements, notch filter timing, transmission line alignments, and receiver field of view mappings inside the tokamak have been accomplished using novel beam profile instrumentation. AUG-CTS commissioning progress will be presented. Plasma measurements in AUG are expected to provide new insights into fast ion physics and to further validate gyrotron CTS as a fast ion diagnostic tool for ITER.

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Textor中快离子的回旋加速器集体汤姆森散射诊断及Asdex升级

只提供摘要形式。目前迫切需要在托卡马克聚变实验中进行限制性快速离子诊断，特别是在ITER和未来的聚变燃烧实验中进行聚变产物α粒子的诊断。为了开发这种诊断能力，并支持当前的快离子等离子体物理研究，在TEXTOR和ASDEX Upgrade (AUG)托卡马克上，利用现有的回旋加速器基础设施和敏感的散射信号接收系统，实施了集体汤姆森散射(CTS)诊断。在TEXTOR有一个180千瓦，110千兆赫的回旋管和一个42通道。6ghz频宽外差接收机在4 ms的时间和10 cm的空间分辨率下，每次等离子体发射可实现高达100 CTS的散射光谱。大散射角(~160度)与可操纵光学使观测快离子空间和场取向各向异性。中性束注入(NBI)和离子回旋加速器加热下的快离子动力学行为研究已经开始，产生了独特的观察结果，在锯齿期间快速离子重新分布，在NBI关闭后减慢。在8月，一个拥有50通道、10ghz带宽接收器的1mw、10ghz双频回旋管模式将用于CTS诊断，其分辨率与TEXTOR相似。精确的回旋管频率测量、陷波滤波器定时、传输线对准和托卡马克内部的接收器视场映射已经使用新型光束剖面仪器完成。将介绍AUG-CTS的调试进度。AUG的等离子体测量有望为快速离子物理提供新的见解，并进一步验证回旋管CTS作为ITER快速离子诊断工具的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2007 IEEE 34th International Conference on Plasma Science (ICOPS)

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