1. Evaluation of shock propagation and preheat from non-Planckian x-ray source driven polystyrene based ablators.
- Author
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Mishra, Gaurav and Ghosh, Karabi
- Subjects
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PLANCK'S energy , *RADIATION sources , *HARD X-rays , *IMPLOSIONS , *ABLATIVE materials , *INERTIAL confinement fusion - Abstract
The effect of non-Planckian radiation source is investigated in pure and 2% silicon doped polystyrene ablator foils by using radiation hydrodynamic simulations, covered over a broad range of drive parameters namely, its strength and hard or M-band x-ray contribution α (ratio of externally imposed Gaussian to original Planck energy density). The spatiotemporal dynamics of shock propagation indicates a large change in rear surface conditions, measured in terms of density and material temperature evolution with the increasing values of α and doping. Different scaling relations, motivated by the generalization of stationary x-ray driven ablation and strong shock theory, are proposed for different variables of interest that suggest a sharp and slow rise with strength and α of incident source, respectively. Just a 2% of silicon doping is able to increase the shock speed by ∼ 9 % and, to reduce the shock breakout and the maximum preheating temperature by ∼ 40 % and ∼ 50 % , respectively for extreme drive conditions. A thorough understanding of the results is important in interpreting the present inertial confinement fusion experiments and proposing the next generation polystyrene based implosion designs for National Ignition Facility. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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