Kinetic simulation of electron cyclotron resonance assisted gas breakdown in split-biased waveguides for ITER collective Thomson scattering diagnostic

arXiv: Plasma Physics Pub Date : 2021-04-29 DOI:10.1063/5.0055461

J. Trieschmann, A. W. Larsen, T. Mussenbrock, S. Korsholm

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引用次数: 1

Abstract

For the measurement of the dynamics of fusion-born alpha particles $E_\alpha \leq 3.5$ MeV in ITER using collective Thomson scattering (CTS), safe transmission of a gyrotron beam at mm-wavelength (1 MW, 60 GHz) passing the electron cyclotron resonance (ECR) in the in-vessel tokamak `port plug' vacuum is a prerequisite. Depending on neutral gas pressure and composition, ECR-assisted gas breakdown may occur at the location of the resonance, which must be mitigated for diagnostic performance and safety reasons. The concept of a split electrically biased waveguide (SBWG) has been previously demonstrated in [C.P. Moeller, U.S. Patent 4,687,616 (1987)]. The waveguide is longitudinally split and a kV bias voltage applied between the two halves. Electrons are rapidly removed from the central region of high radio frequency electric field strength, mitigating breakdown. As a full scale experimental investigation of gas and electromagnetic field conditions inside the ITER equatorial port plugs is currently unattainable, a corresponding Monte Carlo simulation study is presented. Validity of the Monte Carlo electron model is demonstrated with a prediction of ECR breakdown and the mitigation pressure limits for the above quoted reference case with $^1$H$_2$ (and pollutant high $Z$ elements). For the proposed ITER CTS design with a 88.9 mm inner diameter SBWG, ECR breakdown is predicted to occur down to a pure $^1$H$_2$ pressure of 0.3 Pa, while mitigation is shown to be effective at least up to 10 Pa using a bias voltage of 1 kV. The analysis is complemented by results for relevant electric/magnetic field arrangements and limitations of the SBWG mitigation concept are addressed.

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裂变偏置波导中电子回旋共振辅助气体击穿的动力学模拟

为了在ITER中使用集体汤姆逊散射(CTS)测量聚变产生的α粒子$E_\alpha \leq 3.5$ MeV的动力学，在容器内托卡马克“端口塞”真空中安全传输波长为mm (1 MW, 60 GHz)的回旋加速器束通过电子回旋共振(ECR)是先决条件。根据中性气体压力和成分的不同，ecr辅助气体击穿可能发生在谐振位置，出于诊断性能和安全原因，必须减轻这种击穿。分离式电偏波导(SBWG)的概念先前已在[C.P.]中得到证明Moeller, U.S. Patent 4,687,616(1987)]。波导纵向分开，在两半之间施加kV偏置电压。电子迅速从高频电场强度高的中心区域移除，减轻击穿。由于目前无法对ITER赤道端口塞内的气体和电磁场条件进行全面的实验研究，因此提出了相应的蒙特卡罗模拟研究。蒙特卡罗电子模型的有效性得到了验证，并对上述参考情况下$^1$ H $_2$(和污染物高$Z$元素)的ECR击穿和缓解压力极限进行了预测。对于具有88.9 mm内径SBWG的ITER CTS设计，预计ECR击穿将发生在0.3 Pa的纯$^1$ H $_2$压力下，而使用1 kV的偏置电压至少可有效缓解至10 Pa。相关电场/磁场布置的结果补充了这一分析，并解决了SBWG缓解概念的局限性。

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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arXiv: Plasma Physics

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