Ultrafast x-ray imaging of pulsed plasmas in water

Christopher Campbell, Xin Tang, Y. Sechrest, K. Fezzaa, Zhehui Wang, D. Staack
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引用次数: 4

Abstract

Pulsed plasmas in liquids exhibit complex interaction between three phases of matter (liquids, gas, plasmas) and are currently used in a wide range of applications across several fields, however significant knowledge gaps in our understanding of plasma initiation in liquids hinder additional application and control; this area of research currently lacks a comprehensive predictive model. To aid progress in this area experimentally, here we present the first-known ultrafast (50 ps) X-ray images of pulsed plasma initiation processes in water (+25 kV, 10 ns, 5 mJ), courtesy of the X-ray imaging techniques available at Argonne National Laboratory's Advanced Photon Source (APS), with supporting nanosecond optical imaging and a computational X-ray diffraction model. These results clearly resolve narrow (~10 micron) low-density plasma channels during initiation timescales typically obscured by optical emission (<100 ns), a well-known and difficult problem to plasma experiments without access to state-of-the-art X-ray sources such as the APS synchrotron. Images presented in this work speak to several of the prevailing plasma initiation hypotheses, supporting electrostriction and bubble deformation as dominant initiation phenomena. We also demonstrate the plasma setup used in this work as a cheap ($<$US\$100k), compact, and repeatable benchmark imaging target (29.1 km/s, 1 TW/cm$^2$) useful for the development of next-generation ultrafast imaging of high-energy-density physics (HEDP), as well as easier integration of HEDP research into synchrotron-enabled facilities.
水中脉冲等离子体的超快x射线成像
液体中的脉冲等离子体在物质(液体,气体,等离子体)的三个阶段之间表现出复杂的相互作用,目前在几个领域的广泛应用中得到了广泛的应用,然而,我们对液体中的等离子体起始的理解存在重大的知识空白,阻碍了进一步的应用和控制;这一领域的研究目前缺乏一个全面的预测模型。为了帮助这一领域的实验进展,在这里,我们展示了第一张已知的超快(50 ps) x射线图像,显示了脉冲等离子体在水中(+25 kV, 10 ns, 5 mJ)的起始过程,由阿贡国家实验室的先进光子源(APS)提供的x射线成像技术,支持纳秒光学成像和计算x射线衍射模型。这些结果清楚地解决了在起始时间尺度上狭窄(~10微米)的低密度等离子体通道,通常被光学发射(<100 ns)遮挡,这是等离子体实验中一个众所周知的难题,没有最先进的x射线源,如APS同步加速器。在这项工作中呈现的图像说明了几种流行的等离子体起始假说,支持电伸缩和气泡变形作为主要的起始现象。我们还演示了这项工作中使用的等离子体装置作为廉价($<$US\$ 100,000),紧凑和可重复的基准成像目标(29.1 km/s, 1 TW/cm$^2$),用于开发下一代高能量密度物理(HEDP)的超快成像,以及将HEDP研究更容易集成到同步加速器设施中。
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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