Your search keyword '"Riedel WM"' showing total 2 results

1. Neutron imaging of the deuterium-tritium tamping gas volume in an inertial confinement fusion hohlraum.

Author

Izumi N, Higginson DP, Rosen MD, Riedel WM, Haines BM, Fittinghoff DN, Volegov P, Youmans AE, Kemp A, Chapman T, Hardy C, Gjemso J, Waltz C, Rogers SM, Woodworth BN, Sarginson T, Cheung R, Masters N, Sandoval R, Cunningham T, Ramirez R, Holder JP, Reynolds RL, Holunga DM, Briggs TM, Vonhof S, Roskopf NT, Schlossberg D, Moore AS, Kerr S, Hahn KD, Reichelt BL, Mackinnon AJ, Moody JD, Ross JS, and Hinkel D

Abstract

To benchmark the accuracy of the models and improve the predictive capability of future experiments, the National Ignition Facility requires measurements of the physical conditions inside inertial confinement fusion hohlraums. The ion temperature and bulk motion velocity of the gas-filled regions of the hohlraum can be obtained by replacing the helium tamping gas in the hohlraum with deuterium-tritium (DT) gas and measuring the Doppler broadening and Doppler shift of the neutron spectrum produced by nuclear reactions in the hohlraum. To understand the spatial distribution of the neutron production inside the hohlraum, we have developed a new penumbral neutron imager with a 12 mm diameter field of view using a simple tungsten alloy spindle. We performed the first experiment using this imager on a DT gas-filled hohlraum and successfully obtained the spatial distribution of neutron production in the hohlraum plasma. We will report on the design of the spindle, characterization of the detectors, and methodology of the image reconstruction., (© 2024 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2024

2. Developing "inverted-corona" fusion targets as high-fluence neutron sources.

Author

Hohenberger M, Meezan NB, Riedel WM, Kabadi N, Forrest CJ, Aghaian L, Cappelli MA, Farrell M, Glenzer SH, Heeter B, Heredia R, Landen OL, Mackinnon AJ, Petrasso R, Shuldberg CM, Treffert F, and Hsing WW

Abstract

We present experimental studies of inverted-corona targets as neutron sources at the OMEGA Laser Facility and the National Ignition Facility (NIF). Laser beams are directed onto the inner walls of a capsule via laser-entrance holes (LEHs), heating the target interior to fusion conditions. The fusion fuel is provided either as a wall liner, e.g., deuterated plastic (CD), or as a gas fill, e.g., D 2 gas. Such targets are robust to low-mode drive asymmetries, allowing for single-sided laser drive. On OMEGA, 1.8-mm-diameter targets with either a 10-μm CD liner or up to 2 atm of D 2 -gas fill were driven with up to 18 kJ of laser energy in a 1-ns square pulse. Neutron yields of up to 1.5 × 10 10 generally followed expected trends with fill pressure or laser energy, although the data imply some mix of the CH wall into the fusion fuel for either design. Comparable performance was observed with single-sided (1x LEH) or double-sided (2x LEH) drive. NIF experiments tested the platform at scaled up dimensions and energies, combining a 15-μm CD liner and a 3-atm D 2 -gas fill in a 4.5-mm diameter target, laser-driven with up to 330 kJ. Neutron yields up to 2.6 × 10 12 were measured, exceeding the scaled yield expectation from the OMEGA data. The observed energy scaling on the NIF implies that the neutron production is gas dominated, suggesting a performance boost from using deuterium-tritium (DT) gas. We estimate that neutron yields exceeding 10 14 should be readily achievable using a modest laser drive of ∼300 kJ with a DT fill.

Published

2021