Radiation Drive Designed to Extend the Pressure Ranges Measured inGbar Equation of State Experiments at the National Ignition Facility
ORAL
Abstract
We present the design and demonstration of a new radiation temperature drive to increase the
pressure range measured using the existing Gbar experimental platform at the National Ignition
Facility. Using the same peak radiation temperature as data previously published spanning 25–60
Mbar in polystyrene [1], post-shot hydrodynamic simulations suggest the new drive can measure 20–
200 Mbar with the same target design. The drive starts with a low radiation temperature that launches
a weak shock into the sample and is followed by a continuous increase in radiation temperature to
strengthen the leading shock. The additional shock strengthening elevates the pressures within the
sample beyond what is achievable by convergence alone. Design features of the new drive and
accompanying radiation hydrodynamics simulations are used to illustrate the method in which the
pressure range was increased. The design of this drive can be used to significantly increase the
amount of equation of state data collected on each experiment.
[1] T. Döppner et al, Phys. Rev. Lett. 121, 025001 (2018).
pressure range measured using the existing Gbar experimental platform at the National Ignition
Facility. Using the same peak radiation temperature as data previously published spanning 25–60
Mbar in polystyrene [1], post-shot hydrodynamic simulations suggest the new drive can measure 20–
200 Mbar with the same target design. The drive starts with a low radiation temperature that launches
a weak shock into the sample and is followed by a continuous increase in radiation temperature to
strengthen the leading shock. The additional shock strengthening elevates the pressures within the
sample beyond what is achievable by convergence alone. Design features of the new drive and
accompanying radiation hydrodynamics simulations are used to illustrate the method in which the
pressure range was increased. The design of this drive can be used to significantly increase the
amount of equation of state data collected on each experiment.
[1] T. Döppner et al, Phys. Rev. Lett. 121, 025001 (2018).
*This work was performed under the auspices of the U.S. Department of Energy by LawrenceLivermore National Laboratory under Contract DE-AC52-07NA27344 and was supported by theLLNL-LDRD Program under Project No. 22-ERD-005.
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Presenters
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Michael Springstead
- University of Michigan