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朝着更具预测性的腔辐射驱动和对称性模型迈进。

Progress towards a more predictive model for hohlraum radiation drive and symmetry.

作者信息

Jones O S, Suter L J, Scott H A, Barrios M A, Farmer W A, Hansen S B, Liedahl D A, Mauche C W, Moore A S, Rosen M D, Salmonson J D, Strozzi D J, Thomas C A, Turnbull D P

机构信息

Lawrence Livermore National Laboratory, Livermore, California 94551, USA.

Sandia National Laboratory, Albuquerque, New Mexico 87185, USA.

出版信息

Phys Plasmas. 2017 May;24(5):056312. doi: 10.1063/1.4982693. Epub 2017 May 19.

DOI:10.1063/1.4982693
PMID:28611532
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5438280/
Abstract

For several years, we have been calculating the radiation drive in laser-heated gold hohlraums using flux-limited heat transport with a limiter of 0.15, tabulated values of local thermodynamic equilibrium gold opacity, and an approximate model for not in a local thermodynamic equilibrium (NLTE) gold emissivity (DCA_2010). This model has been successful in predicting the radiation drive in vacuum hohlraums, but for gas-filled hohlraums used to drive capsule implosions, the model consistently predicts too much drive and capsule bang times earlier than measured. In this work, we introduce a new model that brings the calculated bang time into better agreement with the measured bang time. The new model employs (1) a numerical grid that is fully converged in space, energy, and time, (2) a modified approximate NLTE model that includes more physics and is in better agreement with more detailed offline emissivity models, and (3) a reduced flux limiter value of 0.03. We applied this model to gas-filled hohlraum experiments using high density carbon and plastic ablator capsules that had hohlraum He fill gas densities ranging from 0.06 to 1.6 mg/cc and hohlraum diameters of 5.75 or 6.72 mm. The new model predicts bang times to within ±100 ps for most experiments with low to intermediate fill densities (up to 0.85 mg/cc). This model predicts higher temperatures in the plasma than the old model and also predicts that at higher gas fill densities, a significant amount of inner beam laser energy escapes the hohlraum through the opposite laser entrance hole.

摘要

多年来,我们一直使用限流器为0.15的通量限制热传输、局部热力学平衡金不透明度的列表值以及非局部热力学平衡(NLTE)金发射率的近似模型(DCA_2010)来计算激光加热金腔中的辐射驱动。该模型在预测真空腔中的辐射驱动方面取得了成功,但对于用于驱动胶囊内爆的充气腔,该模型始终预测的驱动量过多,且胶囊爆炸时间比测量值早。在这项工作中,我们引入了一个新模型,使计算出的爆炸时间与测量的爆炸时间更吻合。新模型采用:(1)在空间、能量和时间上完全收敛的数值网格;(2)一种改进的近似NLTE模型,该模型包含更多物理过程,并且与更详细的离线发射率模型更吻合;(3)将通量限制值降低到0.03。我们将此模型应用于使用高密度碳和塑料烧蚀剂胶囊的充气腔实验,这些胶囊的腔氦填充气体密度范围为0.06至1.6毫克/立方厘米,腔直径为5.75或6.72毫米。对于大多数低至中等填充密度(高达0.85毫克/立方厘米)的实验,新模型预测的爆炸时间在±100皮秒以内。该模型预测等离子体中的温度比旧模型更高,并且还预测在更高的气体填充密度下,大量内束激光能量会通过相对的激光入射孔逸出腔。

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