OPTEMIST: A neutral beam for measuring quasi-omnigenity in Wendelstein 7-X

Physics of Plasmas Pub Date : 2024-07-01 DOI:10.1063/5.0218670

S. Lazerson, David Kulla, P. McNeely, N. Rust, Lucas van Ham, D. Hartmann

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Abstract

A new neutral beamline (OPTEMIST) uniquely capable of exploring the predicted improvement of fast ion confinement in Wendelstein 7-X (W7-X), which comes with increasing plasma beta, is proposed. As the plasma beta increases in the W7-X device, the high mirror magnetic configuration has drift orbits that begin to close, enhancing the confinement of the deeply trapped particles. The existing neutral beam system is found to produce particle populations that do not adequately probe the deeply trapped orbits. Fast tritons generated by thermal deuterium–deuterium fusion reactions are found to probe the necessary conditions for demonstrating this effect. However, it is found that diagnostically measuring this effect will be difficult. A scoping study of a neutral beamline that directly populates the trapped orbits is performed. It is found that a monoenergetic population of 120 kV injected protons provides the largest confinement enhancement in the fast ion population as the plasma beta is increased. The necessity to raise plasma density to increase plasma beta results in blinding of spectroscopic beam measurements by bremsstrahlung. An array of novel fast ion loss detectors that would adequately assess the confinement of these particles is proposed.

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OPTEMIST：用于测量文德尔施泰因 7-X 中准同源性的中性光束

我们提出了一条新的中性光束线（OPTEMIST），该光束线具有独特的能力，能够探索温德斯坦 7-X （W7-X）中快离子禁锢的预测改进，这种改进是随着等离子体贝塔的增加而产生的。随着 W7-X 设备中等离子体贝塔值的增加，高镜磁配置的漂移轨道开始闭合，从而增强了对深度捕获粒子的束缚。研究发现，现有的中性束系统产生的粒子群无法充分探测深困轨道。由氘-氘热核聚变反应产生的快速三顿子被认为能够探测到证明这种效应的必要条件。然而，研究发现，对这种效应进行诊断测量非常困难。对直接填充被困轨道的中性光束线进行了范围研究。研究发现，随着等离子体贝塔值的增加，120 千伏注入质子的单能离子群对快离子群的约束增强最大。由于必须提高等离子体密度才能增加等离子体β，因此轫致辐射会导致光谱束测量失明。建议使用新型快离子损耗探测器阵列，以充分评估这些粒子的封闭性。

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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Physics of Plasmas

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