Laser initiated hollow gas-embedded Z-pinch

2004 International Conference on High-Power Particle Beams (BEAMS 2004) Pub Date : 2002-12-16 DOI:10.1063/1.1531322

H. Chuaqui, R. Aliaga-Rossel, F. Veloso, C. Pavez, M. Favre, I. Mitchell, E. Wyndham

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引用次数: 4

Abstract

Results of new optical method of generating a precursor plasma for a shell gas embedded Z-pinch are presented. Experiments were performed on a pulse power generator using a peak current up to 150 kA with a rise time of 70 ns, 120 ns pulse length. The optical precursor plasma was generated by using a Nd-Y AG laser, 200 ml, 8 ns at 1.06 μm. Two different optical schemes were used, one consists of a combination of lenses capable of producing a hollow beam; while the other uses an axicon to generate the hollow beam. In both cases the hollow beam was focused at the cathode surface where metallic ring plasma, of either 2 or 6 mm diameter, is created. The annular preionization is created immediately before or during the first 30 ns after the line voltage is applied. The discharge was carried out in a chamber filled with hydrogen gas at 1/3 atm. Flat electrodes were used with 10 mm separation. The anode has a 6 mm diameter central hole to allow the passage of the preionizing laser. Optical diagnostics (schlieren, shadowgraphy and interferometry) were performed using the second harmonics of the same laser used to preionize. Preionizing using an axicon results in better formed hollow discharges.

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激光引发的空心气体嵌入z型夹紧

本文介绍了一种新的光学方法，用于产生壳体气体嵌入z箍缩的前驱体。实验在脉冲功率发生器上进行，峰值电流高达150ka，上升时间为70ns，脉冲长度为120ns。采用Nd-Y AG激光器，波长为200 ml，波长为8 ns，波长为1.06 μm。使用了两种不同的光学方案，一种是由能够产生空心光束的透镜组合组成;而另一种则使用轴突产生空心光束。在这两种情况下，空心光束都聚焦在阴极表面，在阴极表面产生直径为2或6毫米的金属环状等离子体。环形预电离是在施加线路电压之前或在施加线路电压后的前30ns内立即产生的。放电在1/3大气压下充满氢气的腔室中进行。采用间距为10 mm的平板电极。阳极有一个6毫米直径的中心孔，以允许预电离激光通过。光学诊断(纹影、阴影成像和干涉测量)使用用于预电离的同一激光的二次谐波进行。使用轴离子预电离可形成更好的空心放电。

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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来源期刊

2004 International Conference on High-Power Particle Beams (BEAMS 2004)

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