Full-torus impurity transport simulation in boron powder injection experiments in the Large Helical Device

IF 2.3 2区物理与天体物理 Q1 NUCLEAR SCIENCE & TECHNOLOGY

Nuclear Materials and Energy Pub Date : 2024-11-04 DOI:10.1016/j.nme.2024.101803

M. Shoji , G. Kawamura , R. Smirnov , J. Romazanov , A. Kirschner , Y. Tanaka , S. Masuzaki , T. Kawate , F. Nespoli , R. Lunsford , E.P. Gilson , S. Brezinsek , N.A. Pablant

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Abstract

The toroidal distribution of boron deposition on plasma-facing components (PFCs) in boron powder injection using an impurity power dropper (IPD) was investigated by full-torus simulation and observations in a systematic plasma density-scan experiment. The images of the ablation of dropped boron powders observed with a visible CCD camera were consistently explained by the simulations of the ablation positions of the boron powders considering the size distribution. Simulations assuming full-torus boron deposition on the PFCs did not reproduce the observed intensity profile of boron emission lines for higher plasma densities. It indicated that the density of boron deposited on PFCs installed toroidally far from the IPD was low for higher plasma densities due to the change in the ablation positions of the boron powders toward the outboard side. The experimental results verified the previous full-torus simulation of the toroidal distribution of the boron deposition in both lower and higher plasma densities.

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大型螺旋装置中硼粉末注入实验的全副弦杂质输运模拟

在使用杂质功率滴注器（IPD）注入硼粉末的过程中，通过在系统性等离子体密度扫描实验中进行的全全周模拟和观测，研究了硼沉积在等离子体面元件（PFC）上的环形分布。用可见光 CCD 相机观察到的滴落硼粉的烧蚀图像与考虑到尺寸分布的硼粉烧蚀位置模拟结果一致。在等离子体密度较高的情况下，假定硼在 PFC 上全周沉积的模拟无法再现所观察到的硼发射线强度曲线。这表明，在等离子体密度较高时，由于硼粉的烧蚀位置向外侧变化，在远离 IPD 的环形安装的 PFC 上沉积的硼密度较低。实验结果验证了之前对较低和较高等离子体密度下硼沉积环形分布的全环形模拟。

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来源期刊

Nuclear Materials and Energy Materials Science-Materials Science (miscellaneous)

CiteScore

3.70

自引率

15.40%

发文量

175

审稿时长

20 weeks

期刊介绍： The open-access journal Nuclear Materials and Energy is devoted to the growing field of research for material application in the production of nuclear energy. Nuclear Materials and Energy publishes original research articles of up to 6 pages in length.