Plasma Diagnostics in T-15MD Divertor: Tasks, Problems, and Implementation Possibilities

IF 0.9 4区物理与天体物理 Q4 PHYSICS, FLUIDS & PLASMAS

Plasma Physics Reports Pub Date : 2024-11-05 DOI:10.1134/S1063780X24601421

K. Yu. Vukolov, E. N. Andreenko, M. Yu. Buzmakov, V. S. Neverov, I. I. Orlovskiy, Yu. I. Tolpegina, D. A. Fedorov

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Abstract

The article considers different methods of divertor plasma diagnostics planned for using in the T‑15MD tokamak. Technical problems arising during operation of optical systems in the divertor zone are discussed, including degradation of in-vessel optical elements. The main attention is paid to the conceptual design of the “Passive Spectroscopy in Divertor” diagnostic system. The optical system, including in-vessel mirrors, and methods for protecting its components from the negative effects of plasma are described in detail. Using synthetic diagnostics and numerical simulation methods, the possibility of solving the problem of tomographic reconstruction of the two-dimensional profile of plasma radiation in the T-15MD divertor is demonstrated. Based on the results presented, it was concluded that passive spectroscopy can be used for obtaining data on plasma parameters in the divertor with good spatial resolution, which will make it possible to study the physics of processes and monitor the operation of the T-15MD divertor, including the operation in detachment regime.

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T-15MD 分流器中的等离子体诊断：任务、问题和实施可能性

文章考虑了计划在 T-15MD 托卡马克中使用的不同岔流等离子体诊断方法。文章讨论了岔流区光学系统运行过程中出现的技术问题，包括舱内光学元件的退化。主要关注 "憩息器中的被动光谱 "诊断系统的概念设计。详细介绍了包括舱内反射镜在内的光学系统，以及保护其元件免受等离子体负面影响的方法。利用合成诊断和数值模拟方法，展示了解决 T-15MD 分流器中等离子体辐射二维剖面层析重建问题的可能性。根据所提供的结果，得出的结论是，被动光谱学可用于获取具有良好空间分辨率的转发器内等离子参数数据，这将使研究物理过程和监测 T-15MD 转发器的运行（包括在分离状态下的运行）成为可能。

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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来源期刊

Plasma Physics Reports 物理-物理：流体与等离子体

CiteScore

1.90

自引率

36.40%

发文量

104

审稿时长

4-8 weeks

期刊介绍： Plasma Physics Reports is a peer reviewed journal devoted to plasma physics. The journal covers the following topics: high-temperature plasma physics related to the problem of controlled nuclear fusion based on magnetic and inertial confinement; physics of cosmic plasma, including magnetosphere plasma, sun and stellar plasma, etc.; gas discharge plasma and plasma generated by laser and particle beams. The journal also publishes papers on such related topics as plasma electronics, generation of radiation in plasma, and plasma diagnostics. As well as other original communications, the journal publishes topical reviews and conference proceedings.