Improving the hot-spot pressure and demonstrating ignition hydrodynamic equivalence in cryogenic deuterium–tritium implosions on OMEGA

Goncharov, V. N.; Sangster, T. C.; Betti, R.; Boehly, T. R.; Bonino, M. J.; Collins, T. B.; Craxton, R. S.; Delettrez, J. A.; Edgell, D. H.; Epstein, R.; Follett, R. K.; Forrest, C. J.; Froula, D. H.; Yu. Glebov, V.; Harding, D. R.; Henchen, R. J.; Hu, S. X.; Igumenshchev, I. V.; Janezic, R.; Kelly, J. H.; Kessler, T. J.; Kosc, T. Z.; Loucks, S. J.; Marozas, J. A.; Marshall, F. J.; Maximov, A. V.; McCrory, R. L.; McKenty, P. W.; Meyerhofer, D. D.; Michel, D. T.; Myatt, J. F.; Nora, R.; Radha, P. B.; Regan, S. P.; Seka, W.; Shmayda, W. T.; Short, R. W.; Shvydky, A.; Skupsky, S.; Stoeckl, C.; Yaakobi, B.; Frenje, J. A.; Gatu-Johnson, M.; Petrasso, R. D.; Casey, D. T.

doi:10.1063/1.4876618

Title: Improving the hot-spot pressure and demonstrating ignition hydrodynamic equivalence in cryogenic deuterium–tritium implosions on OMEGA

Journal Article · Fri May 23 00:00:00 EDT 2014 · Physics of Plasmas

DOI:https://doi.org/10.1063/1.4876618· OSTI ID:1132835

Goncharov, V. N. ^[1]; Sangster, T. C. ^[1]; Betti, R. ^[1]; Boehly, T. R. ^[1]; Bonino, M. J. ^[1]; Collins, T. B. ^[1]; Craxton, R. S. ^[1]; Delettrez, J. A. ^[1]; Edgell, D. H. ^[1]; Epstein, R. ^[1]; Follett, R. K. ^[1]; Forrest, C. J. ^[1]; Froula, D. H. ^[1]; Yu. Glebov, V. ^[1]; Harding, D. R. ^[1]; Henchen, R. J. ^[1]; Hu, S. X. ^[1]; Igumenshchev, I. V. ^[1]; Janezic, R. ^[1]; Kelly, J. H. ^[1] more »

Laboratory for Laser Energetics, University of Rochester 1 , Rochester, New York 14623, USA
Massachussets Institute of Technology 2 , Plasma Science and Fusion Center, Cambridge, Massachusetts 02139, USA
Lawrence Livermore National Laboratory 3 , Livermore, California 94551, USA

Reaching ignition in direct-drive (DD) inertial confinement fusion implosions requires achieving central pressures in excess of 100 Gbar. The OMEGA laser system [T. R. Boehly et al., Opt. Commun. 133, 495 (1997)] is used to study the physics of implosions that are hydrodynamically equivalent to the ignition designs on the National Ignition Facility (NIF) [J. A. Paisner et al., Laser Focus World 30, 75 (1994)]. It is shown that the highest hot-spot pressures (up to 40 Gbar) are achieved in target designs with a fuel adiabat of α ≃ 4, an implosion velocity of 3.8 × 107 cm/s, and a laser intensity of ∼1015 W/cm2. These moderate-adiabat implosions are well understood using two-dimensional hydrocode simulations. The performance of lower-adiabat implosions is significantly degraded relative to code predictions, a common feature between DD implosions on OMEGA and indirect-drive cryogenic implosions on the NIF. Simplified theoretical models are developed to gain physical understanding of the implosion dynamics that dictate the target performance. These models indicate that degradations in the shell density and integrity (caused by hydrodynamic instabilities during the target acceleration) coupled with hydrodynamics at stagnation are the main failure mechanisms in low-adiabat designs. To demonstrate ignition hydrodynamic equivalence in cryogenic implosions on OMEGA, the target-design robustness to hydrodynamic instability growth must be improved by reducing laser-coupling losses caused by cross beam energy transfer.

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Research Organization:: Univ. of Rochester, NY (United States). Lab. for Laser Energetics; Massachusetts Inst. of Technology (MIT), Cambridge, MA (United States). Plasma Science and Fusion Center

Sponsoring Organization:: USDOE

DOE Contract Number:: NA0001944; NA0001857

OSTI ID:: 1132835

Report Number(s):: DOE/NA/1944-1171; 2013-92; 2137

Journal Information:: Physics of Plasmas, Vol. 21, Issue 5; ISSN 1070-664X

Publisher:: American Institute of Physics (AIP)

Country of Publication:: United States

Language:: English

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