提高激光诱导惰性气体等离子体光源点火效率的方法

Q4 Engineering
Naoya Matsumoto, K. Fujita
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引用次数: 0

摘要

激光诱导惰性气体等离子体光源具有高亮度、高稳定性、宽光谱和长寿命等特点。本研究展示了将靶点燃方法应用于四种靶材料(钨、铂、钍化钨和氧化钡浸渍钨)的新结构的效果。与以往的实验相比,我们提出的条件使这种高亮度光源的实际应用具有一个数量级的激光功率降低。首先,所提出的结构不同于以前的目标方法的线结构。其次,根据加热时间对每种材料的点火效率进行定量评价。结果表明:四种材料中,BI的连续点火功率最低(35 W),且重复点火效果最好;这意味着功函数决定了点火效率。最后,阐明了点火过程。在点火前的氙气区激光照射下,对靶材中的钡原子和离子进行了实验观察。作为一种电子发射材料,钡具有低功函数。因此,我们假设目标表面通过激光加热将钡发射到氙气区。我们预计,由于钡的功函数低,它会迅速释放出许多电子,逆韧致吸收会瞬间增加,最终点燃氙气。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Improved Ignition Efficiency in Method for Laser-induced Noble Gas Plasma Light Source
High brightness and stability, a broadband spectrum, and a long lifespan characterize a laser-induced noble gas plasma light source. This study shows the effects of applying the target ignition method to a new structure for four target materials (tungsten, platinum, thoriated tungsten, and tungsten impregnated with barium oxide (BI)). Compared with previous experiments, our proposed conditions enable practical use of this high brightness light source with a one order of magnitude lower laser power. First, the proposed structure is different from a previous wire structures for the target method. Second, the ignition efficiency of each material was quantitatively evaluated according to heating time. Results showed that among the four materials, BI could be ignited with the lowest laser power (continuous wave: 35 W), and could best repeat ignition. This implies that the work function determines ignition efficiency. Finally, we clarify the ignition process. Barium atoms and ions from the target were experimentally observed under laser irradiation in the xenon gas region before ignition. Barium has a low work function as an electron emission material. Therefore, we hypothesized that the target surface emitted barium into the xenon gas region by laser heating. We expected that the barium would rapidly discharge many electrons owing to its low work function, the inverse bremsstrahlung absorption would instantaneously increase, and finally, it would ignite the xenon gas.
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来源期刊
Journal of the Illuminating Engineering Institute of Japan (Shomei Gakkai Shi)
Journal of the Illuminating Engineering Institute of Japan (Shomei Gakkai Shi) Engineering-Electrical and Electronic Engineering
CiteScore
0.10
自引率
0.00%
发文量
6
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