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How numerical simulations helped to achieve breakeven on the NIF.

Authors :
Marinak, M. M.
Zimmerman, G. B.
Chapman, T.
Kerbel, G. D.
Patel, M. V.
Koning, J. M.
Sepke, S. M.
Chang, B.
Schroeder, C. R.
Harte, J. A.
Bailey, D. S.
Taylor, L. A.
Langer, S. H.
Belyaev, M. A.
Clark, D. S.
Gaffney, J.
Hammel, B. A.
Hinkel, D. E.
Kritcher, A. L.
Milovich, J. L.
Source :
Physics of Plasmas; Jul2024, Vol. 31 Issue 7, p1-17, 17p
Publication Year :
2024

Abstract

The inertial confinement fusion program relies upon detailed simulations with inertial confinement fusion (ICF) codes to design targets and to interpret the experimental results. These simulations treat as much physics from essential principles as is practical, including laser deposition, cross beam energy transfer, x-ray production and transport, nonlocal thermal equilibrium kinetics, thermal transport, hydrodynamic instabilities, thermonuclear burn, and transport of reaction products. Improvements in radiation hydrodynamic code capabilities and vast increases in computing power have enabled more realistic, accurate 3D simulations that treat all known asymmetry sources. We describe how numerical simulations helped to guide the program, assess the impediments to breakeven, and optimize every aspect of target design. A preshot simulation of the first National Ignition Facility experiment that surpassed breakeven predicted an increased yield that matches the experimental result, within the preshot predicted uncertainty, with a target gain of 1.5. We will cover the key developments in Lawrence Livermore National Laboratory ICF codes that enabled these simulations and give specific examples of how they helped to guide the program. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
1070664X
Volume :
31
Issue :
7
Database :
Complementary Index
Journal :
Physics of Plasmas
Publication Type :
Academic Journal
Accession number :
178780493
Full Text :
https://doi.org/10.1063/5.0204710