利用激光吸收技术探索LANSCE氢离子源内部的实验设计

D. Kleinjan, G. Rouleau, L. Neukirch
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引用次数: 0

摘要

洛斯阿拉莫斯中子科学中心(LANSCE)的氢离子源(LHIS)已经为几十年的LANL任务需求提供了稳定的输出。虽然内部已经对其稳定性和寿命进行了一些改进,但其最大光束输出仍然保持在~14 mA。虽然在操作上很好地理解,但LHIS等离子体、铯分布(产生H -离子的催化剂)和产生的H -束之间的内在关系仍然是一个谜,只能通过模型间接探索。我们将开发快速、准确、无创的诊断技术来测量LHIS内部的Cs和H -密度。这些诊断是基于光学吸收光谱,这是在过去十年中发展起来的基于聚变的氢离子源,可以很容易地应用于基于加速器的LHIS。激光吸收技术(LAT)是光学吸收光谱的一种改进形式,它利用调谐到给定原子种类的激光来测量其密度。在这种情况下,将使用调谐到铯的D2线的激光来确定其在LHIS中的密度。类似地,LAT的一个改进版本,称为腔环-环下光谱(CRDS)技术,利用调谐到H -光分离的激光来测量LHIS内部的H -密度。随着这些诊断技术的成功发展,在LHIS的建模和操作中,任何隐藏或休眠的能力都将被发现和利用。同时,它对LANSCE和LANL未来需求的潜在好处也将得到实现。更一般地说,这将是这些等离子体诊断技术首次在基于氢离子源的加速器上使用。我们将介绍诊断设置的初步状态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of experiment to explore inside the LANSCE H− ion source with laser absorption techniques
The Los Alamos Neutron Science Center (LANSCE) H− ion source (LHIS) has provided stable output for decades of LANL mission needs. While several in-house improvements have been made to its stability and lifetime, its maximum beam output has remained the same at ~14 mA. While operationally well understood, the internal relationship between the LHIS plasma, cesium distribution (the catalyst for producing H− ions), and produced H− beam remains a mystery, only explored indirectly with models. We will develop fast, accurate, and non-invasive diagnostics techniques to measure the Cs and H− densities inside LHIS. These diagnostics are based on optical absorption spectroscopy that have been developed in the last decade for fusion based H- ion sources that can readily be applied to the accelerator based LHIS. A refined form of optical absorption spectroscopy, the laser absorption technique (LAT), utilizes lasers tuned to a given atomic species to measure its density. In this case a laser tuned to the D2 line of cesium will be used to determine its density inside LHIS. Similarly, a refined version of LAT called the cavity ring-ring down spectroscopy (CRDS) technique utilizes a laser tuned to H− photo-detachment to measure the H− densities at inside LHIS. With successful development of these diagnostic techniques, any hidden or dormant capabilities in LHIS will be found and capitalized upon, both in its modelling and operation. Also, its potential benefit to LANSCE and LANL future needs will be realized. More generally, this will be the first use of these plasma diagnostic techniques on an accelerator based H− ion sources. We will present on the preliminary status of the diagnostic setup.
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