Beryllium–tungsten graded density inner shells in double shell capsules for improved hydrodynamic stability

The outer surface of the high-Z inner shell in the double shell configuration of inertial confinement fusion experiments experiences Rayleigh–Taylor instability growth during the implosion process due to inverted density and pressure gradients between a highly compressed foam interstitial layer and...

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Veröffentlicht in:Physics of plasmas 2024-11, Vol.31 (11)
Hauptverfasser: Stark, D. J., Loomis, E. N., Sauppe, J. P., Vazirani, N. N., Palaniyappan, S., Bradley, P. A., Rasmus, A., Robey, H. F., Haines, B. M., Merritt, E. C., Sacks, R. F., Sagert, I., Keiter, P. A.
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Sprache:eng
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Zusammenfassung:The outer surface of the high-Z inner shell in the double shell configuration of inertial confinement fusion experiments experiences Rayleigh–Taylor instability growth during the implosion process due to inverted density and pressure gradients between a highly compressed foam interstitial layer and the accelerating dense inner shell. Graded density layers have long been known to reduce instability growth rates. In this study, we employ high-fidelity radiation hydrodynamic simulations to demonstrate this improved stability when grading beryllium into tungsten. We first characterize the response to L-band preheat of these layers using a newly calibrated radiation drive. While graded layer capsules suffer reduced performance (here, measured as DD neutron yield from a CD foam fuel) in 1D simulations due to reduced kinetic energy coupling and reduced fuel compression, they suffer less of a performance drop when 2D instabilities are accounted for. With the improved stability of graded layers, we explore the performance of capsules with larger fuel radii and thinner shells as a preliminary study to find new designs in which graded layers produce the highest yields.
ISSN:1070-664X
1089-7674
DOI:10.1063/5.0203403