An Experiment Simulating the Production, Capture, and Detection of 8Li from an ICF Implosion

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Date
2023-04-15 , 2022-10-17
Authors
Lei, Chunsun
Hotchkiss, Andrew
Brown, Adam E.
Martin, Andrew L.
Yuly, Mark
McLean, James G.
Padalino, Stephen J.
Forrest, Chad J.
Sangster, Thomas C.
Regan, Sean P.
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Houghton University
Abstract
Inertial confinement fusion (ICF) is a possible tool for measuring light-ion nuclear cross sections. One way to do this might be to trap and detect the radioactive decays of the product nuclei produced using a doped target capsule. Some of the highest yield light-ion reactions that could be studied using this technique are 6Li(t,p) 8Li and 9Be(t,α) 8Li, both of which produce 8Li . In order to simulate this method, a natural lithium film was deposited onto a tungsten substrate, which was then activated via the 7Li(d,p) 8Li reaction using the SUNY Geneseo Pelletron accelerator. A current pulse of up to 1000 A was discharged through the tungsten raising its temperature to as high as about 1500 °C in less than a few milliseconds, causing the lithium to rapidly evaporate and produce a gas of neutral lithium atoms which then travelled outward and stuck to the aluminum getter detector foil of the Short-Lived Isotope Counting System (SLICS). This phoswich detector was used to identify beta particles and count in situ the 840 ms beta decay curve for 8Li as a function of time in order to estimate the efficiency of SLICS for trapping and detecting ICF reaction products. Funded in part by a grant from the DOE through the Laboratory for Laser Energetics, and by SUNY Geneseo and Houghton University.
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XLI Annual Rochester Symposium for Physics Students, University of Rochester (Rochester, NY), April 15, 2023.
64th Annual Meeting of the APS Division of Plasma Physics, Spokane, WA, October 17-21, 2022.
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