Open AccessSymmetry control in subscale near-vacuum hohlraums
Author(s) -
D. Turnbull,
L. Berzak Hopkins,
S. Le Pape,
L. Divol,
N. B. Meezan,
O. L. Landen,
D. Ho,
A. J. Mackin,
A. B. Zylstra,
H. G. Rinderknecht,
H. Sio,
R. D. Petrasso,
J. S. Ross,
S. F. Khan,
A. Pak,
E. L. Dewald,
D. A. Callahan,
O. A. Hurricane,
W. W. Hsing,
M. J. Edwards
Publication year - 2016
Publication title -
physics of plasmas
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.75
H-Index - 160
eISSN - 1089-7674
pISSN - 1070-664X
DOI - 10.1063/1.4950825
Subject(s) - hohlraum , physics , national ignition facility , inertial confinement fusion , symmetry (geometry) , optics , laser , pulse (music) , ignition system , beam (structure) , atomic physics , geometry , detector , mathematics , thermodynamics
Controlling the symmetry of indirect-drive inertial confinement fusion implosions remains a key challenge. Increasing the ratio of the hohlraum diameter to the capsule diameter (case-to-capsule ratio, or CCR) facilitates symmetry tuning. By varying the balance of energy between the inner and outer cones as well as the incident laser pulse length, we demonstrate the ability to tune from oblate, through round, to prolate at a CCR of 3.2 in near-vacuum hohlraums at the National Ignition Facility, developing empirical playbooks along the way for cone fraction sensitivity of various laser pulse epochs. Radiation-hydrodynamic simulations with enhanced inner beam propagation reproduce most experimental observables, including hot spot shape, for a majority of implosions. Specular reflections are used to diagnose the limits of inner beam propagation as a function of pulse length.
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