金属表面等离子体的多波段时间分辨光谱:实验与等离子体光谱建模的比较

S. Fuelling, B. Bauer, I. Lindemuth, R. Siemon, K. Yates
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引用次数: 0

摘要

只提供摘要形式。在MTF衬垫压缩实验中,MG磁场在压缩过程中加热内胆表面,可能导致气体或等离子体的形成以及壁材与燃料的混合。为了研究导致等离子体从内部金属衬垫表面形成的条件,在1 ma Zebra发电机上进行了实验,通过将快速上升(1.1×1013 a /s上升速率)的电流通过直径在0.5 mm到2mm之间的“杠铃”形铝(Al 6061)和铜(Cu 101)棒。杠铃形状避免了弧之间的直接视线在接触和受热表面的调查。当表面磁场接近2.2 MG时,观察到等离子体的形成。1,2,3实验还满足了对辐射mhd和等离子体光谱建模基准的详细实验数据的需求。金属等离子体通过紫外(266 nm)和可见光(532 nm) 2帧激光阴影成像、多帧光学成像、滤波可见光和EUV光度测量以及时间分辨可见光和EUV光谱进行了很好的表征。等离子体形成的磁场阈值,膨胀速度,等离子体温度,以及可见光和EUV波段的发射与各种数值模拟的结果进行了比较,包括拉格朗日和欧拉,使用了几组不同的EOS,电阻率和不透明度表。5,6首次对该铝等离子体进行了光谱质量辐射输运视距积分。MHRDR5模拟的辐射- mhd建模结果被用作PrismSPECT光谱建模的输入。视距积分考虑了每一等离子体层的发射、吸收和透射,最后与EUV光谱仪的分辨率有关。所得的模拟光谱与实验的EUV光谱具有较好的一致性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multiband time-resolved spectra of metal surface plasmas: Comparison of experiment with plasma spectroscopic modeling
Summary form only given. In MTF liner compression experiments, MG magnetic fields heat up the inner liner surface during compression, possibly leading to gas or plasma formation and mixing of wall material with the fuel. To investigate the conditions leading to plasma formation from an inner metal liner surface, experiments have been performed on the 1-MA Zebra generator, by passing a fast-rising (1.1×1013 A/s rise rate) current through `barbell'-shaped aluminum (Al 6061) and copper (Cu 101) rods with diameters between 0.5 mm and 2 mm. The barbell shape avoids direct line-of-sight between arcs at contacts and the heated surface under investigation. Plasma formation is observed when the surface magnetic field approaches 2.2 MG for Al.1, 2, 3 The experiment also fulfills a need for detailed experimental data to benchmark radiation-MHD and plasma spectroscopy modeling. The metal plasma is well characterized by UV (266 nm) and visible (532 nm) 2-frame laser shadowgraphy, multi-frame optical imaging, filtered visible4 and EUV photometric measurements, and timeresolved visible and EUV spectroscopy. The magnetic field threshold for plasma formation, the expansion speed, the plasma temperature, and the emissions in visible and EUV bands have been compared with the results of a variety of numerical simulations, both Lagrangian and Eulerian, using several different sets of EOS, resistivity, and opacity tables.5,6 For the first time, a spectroscopic quality radiation transport line-of-sight integration for this Al plasma has been performed. Radiation-MHD modeling results from the MHRDR5 simulation is used as input for PrismSPECT spectral modeling. The line-of-sight integration takes into account the emission, absorption, and transmission of each plasma layer and finally is convoluted with the resolution of the EUV spectrometer. The resultant simulated spectrum compares well with the experimental EUV spectra.
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