Time-Resolved Fuel Density Profiles of the Stagnation Phase of Indirect-Drive Inertial Confinement Implosions

Riccardo Tommasini,O. L. Landen,L. F. Berzak Hopkins,S. P. Hatchett,Daniel H. Kalantar,W. W. Hsing,D. A. Alessi,S L Ayers,Suhas Bhandarkar,Mark Bowers,D. K. Bradley,A. D. Conder,J. M. Di Nicola,P. Di Nicola,Laurent Divol,David N. Fittinghoff,G. Gururangan,G. N. Hall,M Hamamoto,D. R. Hargrove,Edward Hartouni,J. Heebner,S. I. Herriot,Mark R. Hermann,J. P. Holder,D. M. Holunga,D. Homoelle,C.A. Iglesias,Nobuhiko Izumi,A. J. Kemp,T. Kohut,Jeremy Kroll,K. N. LaFortune,J. K. Lawson,R Lowe Webb,A. J. Mackinnon,D Martínez,N. D. Masters,M. P. Mauldin,Jose Milovich,Abbas Nikroo,J. K. Okui,J. Park,M. Prantil,L.J. Pelz,M. Schoff,R. Sigurdsson,Petr L. Volegov,S. Vonhof,T. L. Zobrist,R. J. Wallace,C. F. Walters,Paul J. Wegner,C. C. Widmayer,W. H. Williams,K. Youngblood,M. J. Edwards,M. C. Herrmann

Time-Resolved Fuel Density Profiles of the Stagnation Phase of Indirect-Drive Inertial Confinement Implosions

2020

The implosion efficiency in inertial confinement fusion depends on the degree of stagnated fuel compression, density uniformity, sphericity, and minimum residual kinetic energy achieved. Compton scattering-mediated 50-200 keV x-ray radiographs of indirect-drive cryogenic implosions at the National Ignition Facility capture the dynamic evolution of the fuel as it goes through peak compression, revealing low-mode 3D nonuniformities and thicker fuel with lower peak density than simulated. By differencing two radiographs taken at different times during the same implosion, we also measure the residual kinetic energy not transferred to the hot spot and quantify its impact on the implosion performance.

Keywords:

Mechanics
Physics
Inertial confinement fusion

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