The mix of shell material into the fuel of inertial confinement fusion (ICF) implosions is thought to be a major cause of the failure of most ICF experiments to achieve the fusion yield predicted by computer codes. Implosion asymmetry is a simple measurable quantity that is expected to affect the mix. In order to measure the coupling of asymmetry to mix in ICF implosions, we have performed experiments on the OMEGA laser [T. R. Boehly , Rev. Sci. Instrum. 66, 508 (1995)] that vary the energy of each of the sixty beams individually to achieve a given fraction of L2, the second-order Legendre polynomial. Prolate, symmetric, and oblate implosions resulted. Three different fill pressures were used. Simultaneous x-ray and neutron images were obtained. The experiments were modeled with a radiation/hydrodynamics code using the multi-fluid interpenetration mix model of Scannapieco and Cheng. It fits the data well with a single value of its one adjustable parameter (0.07+/-0.01). This agreement is demonstrated by neutron yield, x-ray images, neutron images, and ion temperatures. The degree of decline of the neutron yield with asymmetry at different fill pressures provides a hard constraint on ICF mix modeling. (C) 2004 American Institute of Physics.
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机译:壳材料混入惯性约束聚变(ICF)内燃的燃料被认为是大多数ICF实验未能实现计算机代码预测的聚变产量的主要原因。内爆不对称性是一个简单的可测量量,预计会影响混合。为了测量ICF内爆中不对称混合的耦合,我们在OMEGA激光器上进行了实验[T. R. Boehly,修订版仪器[第66卷,第508页(1995)]分别改变了六十个光束中每一个的能量,以获得L2的给定分数,即二阶勒让德多项式。产生扁平,对称和扁平内爆。使用了三种不同的填充压力。同时获得了X射线和中子图像。使用Scannapieco和Cheng的多流体互穿混合模型,用辐射/流体力学代码对实验进行建模。它使用一个可调参数的单个值(0.07 +/- 0.01)很好地拟合了数据。中子产率,X射线图像,中子图像和离子温度证明了这一一致性。在不同填充压力下,中子产率随不对称性的下降程度为ICF混合模型提供了严格的约束。 (C)2004美国物理研究所。
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机译:用等离子体约束实现重力场的动态控制热核聚变(TLTS)方法,通过热辐射等离子体绝缘的壁反应堆防止中子辐射并节省磁场和等离子体的混合,使用旋转磁场的异步磁惯性约束反应堆(AMITYAR和HFM)为实施该方法,在该反应器中点燃热核反应的方法,爆炸式等离子发生器(VIP)的实施方法,以及具有HFM的特立普安瓿,以实现D + T反应和具有超高温热度的HFM D +3НЕ和1Н+11В的高温反应
