Plasma Formation, Evolution, and Dynamics in 100-1000 TW Vacuum-Transmission-Line Post-Hole Convolutes

2007 IEEE 34th International Conference on Plasma Science (ICOPS) Pub Date : 2007-06-17 DOI:10.1109/PPPS.2007.4345514

D. Rose, D. Welch, T. Hughes, R. Clark, W. Stygar

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引用次数: 4

Abstract

Summary form only given. Vacuum post-hole convolutes are a critical component in present and future high-power z-pinch drivers. A post-hole convolute is used to join several transmission lines in parallel, transferring the combined currents to a single transmission line attached to a load. Magnetic insulation is lost at positions inside the convolute due to the formation of magnetic-field nulls. Electron sheath-current losses in the convolute region of transmission lines have been explored previously. As power levels for planned z-pinch facilities are increased, the formation of electrode plasmas represents an additional potential power-flow loss mechanism. The 3D particle-in-cell code LSP is being used to study the dynamics of electrode plasmas in post-hole convolutes. The simulations use an implicit field-solver and particle advance for modeling the evolution of the dense plasmas. Simulations of the Z accelerator double-post-hole convolutes and load region that include cathode-and anode-plasma formation in the vicinity of the convolute are being conducted. Potential electrical power loss in this region due to the presence of these plasmas is estimated. In addition, simulations of triple-post-hole convolute designs supporting future z-pinch accelerators are also in progress. Available results will be presented.

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等离子体的形成、演化和动力学在100-1000 TW真空传输在线孔后卷积

只提供摘要形式。真空孔后卷积是当前和未来大功率z捏缩驱动器的关键部件。后孔旋涡用于并联几条传输线，将组合电流传输到连接在负载上的一条传输线上。由于磁场空洞的形成，磁绝缘在涡旋内部的位置丢失。在传输线的绕线区域，电子鞘电流损耗已经被研究过了。随着计划中的z夹紧装置功率水平的增加，电极等离子体的形成代表了额外的潜在功率流损失机制。利用三维细胞内粒子编码LSP研究了电极等离子体在空穴后卷积中的动力学。模拟使用隐式场求解器和粒子推进来模拟密集等离子体的演化。模拟了Z加速器双柱孔涡旋和载荷区域，包括涡旋附近的阴极和阳极等离子体形成。由于这些等离子体的存在，估计该区域的潜在电力损失。此外，支持未来z箍缩加速器的三孔后卷积设计的模拟也在进行中。将提供可用的结果。

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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2007 IEEE 34th International Conference on Plasma Science (ICOPS)

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