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Experimentally Inferred Fusion Yield Dependencies of OMEGA Inertial Confinement Fusion Implosions

A. Lees, R. Betti, J. P. Knauer, V. Gopalaswamy, D. Patel, K. M. Woo, K. S. Anderson, E. M. Campbell, D. Cao, Jonathan Carroll-Nellenback, R. Epstein, C. Forrest, V. N. Goncharov, D. R. Harding, S. X. Hu, I. V. Igumenshchev, R. T. Janezic, Owen Mannion, P. B. Radha, S. P. Regan, A. Shvydky, R. C. Shah, W.T. Shmayda, C. Stoeckl, W. Theobald, C. A. Thomas

2021Physical Review Letters44 citationsDOIOpen Access PDF

Abstract

Statistical modeling of experimental and simulation databases has enabled the development of an accurate predictive capability for deuterium-tritium layered cryogenic implosions at the OMEGA laser [V. Gopalaswamy et al.,Nature 565, 581 (2019)10.1038/s41586-019-0877-0]. In this letter, a physics-based statistical mapping framework is described and used to uncover the dependencies of the fusion yield. This model is used to identify and quantify the degradation mechanisms of the fusion yield in direct-drive implosions on OMEGA. The yield is found to be reduced by the ratio of laser beam to target radius, the asymmetry in inferred ion temperatures from the ℓ=1 mode, the time span over which tritium fuel has decayed, and parameters related to the implosion hydrodynamic stability. When adjusted for tritium decay and ℓ=1 mode, the highest yield in OMEGA cryogenic implosions is predicted to exceed 2×10^{14} fusion reactions.

Topics & Concepts

Inertial confinement fusionImplosionOmegaYield (engineering)TritiumNuclear physicsRADIUSPhysicsDeuteriumFusionFusion powerNuclear fusionNuclear engineeringThermonuclear fusionAtomic physicsPlasmaMaterials scienceThermodynamicsComputer scienceLinguisticsEngineeringPhilosophyQuantum mechanicsComputer securityLaser-Plasma Interactions and DiagnosticsLaser-induced spectroscopy and plasmaCold Fusion and Nuclear Reactions
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