提出了MTF靶等离子体的生成和压缩方法

R. Kirkpatrick, R. S. Thurston, R. Chrein, J. Guzik, A. Sgro, D. Scudder, F. Wysocki, J. Fernández, J. Shlachter, I. Lindemuth, P. Sheehey
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引用次数: 0

摘要

磁化靶聚变(MTF)是一种避免了传统惯性约束和磁约束方法的困难的受控聚变方法,它将磁热绝缘等离子体流体动力压缩到聚变条件下。利用现有的相对便宜的驱动器,如脉冲功率装置(包括爆炸性脉冲功率),将磁热绝缘等离子体压缩到聚变点火条件似乎是可能的。因此,MTF可能代表了一种以非常小的资本投资来展示和研究点燃等离子体的方法。正在进行的LANL爆炸脉冲功率合作与俄罗斯VNIIEF实验室在Arzamas 16部分是由这一应用的动机。我们建议通过以下方式来证明磁化目标聚变的可行性:(1)创造一个合适的磁化目标等离子体,(2)利用现有的脉冲功率设备进行初步的线性压缩实验并演示线性性能。所需的等离子体条件因不同的驱动器而异,但大致描述为温度bbbb50 eV,密度b>0 /sup -6/ gm/cm/sup 3/,电流几百千安培,尺寸为1到几厘米(给出约50 kG的嵌入式磁场)。创建目标等离子体的初始候选是光纤引发的Z-pinch。已经使用相关参数创建了这些压缩,但需要针对MTF应用程序进行优化。目标等离子体将在静态衬垫内进行诊断和优化,使用干涉测量法、光谱学和其他诊断工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Proposed generation and compression of a target plasma for MTF
Magnetized target fusion (MTF), in which a magnetothermally insulated plasma is hydrodynamically compressed to fusion conditions, represents an approach to controlled fusion which avoids difficulties of both traditional inertial confinement and magnetic confinement approaches. It appears possible to compress a magnetothermally insulated plasma to fusion ignition conditions using existing, relatively inexpensive drivers, such as pulsed power devices (including explosive pulsed power). Hence, MTF may represent a means to demonstrate and study ignited plasmas with a very small capital investment. An ongoing LANL explosive pulsed power collaboration with the Russian VNIIEF Laboratory at Arzamas 16 is partly motivated by this application. We are proposing to demonstrate the feasibility of magnetized target fusion by: (1) creating a suitable magnetized target plasma, and (2) performing preliminary liner compression experiments using existing pulsed power facilities and demonstrated liner performance. The required plasma conditions vary for different drivers, but are approximately described by temperature >50 eV, density >10/sup -6/ gm/cm/sup 3/, current of several hundred kiloamperes, and dimensions of one to a few cm (giving an embedded magnetic field of about 50 kG). The initial candidate for creating the target plasma is a fiber-initiated Z-pinch. These pinches have already been created with relevant parameters, but need to be optimized for the MTF application. The target plasma would be diagnosed and optimized inside a static liner, using interferometry, spectroscopy, and other diagnostic tools.
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