Radiation Hydrodynamics

Heating Deuterium and Tritium (DT) to ignition temperatures is the easiest approach to fusion energy. ICF involves compressing a ~1 mm capsule ("target") to high densities. The target is spherically imploded using a high power (~100 TW) driver, high power lasers being the most common driver. Ablation of the outer surface of the target drives a series of radial shock waves into the target, compressing the target and heating it to thermonuclear temperatures. High energy alpha particles created from the fusion of Deuterium and Tritium propagate out through cold DT fuel and deposit energy. This energy leads to a propagating burn wave which ignites the remaining fuel and cause the release of significant amounts of energy. Radiation hydrodynamics is the study of that process.

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FTI Publications

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UWFDM-1208   Verification and Analysis of the Radiation Transport Packages in the BUCKY 1-D Radiation-Hydrodynamics Code; Gregory A. Rochau, June 2003. (89 pages, 1.7 MB)

UWFDM-1280   Z-Pinch (LiF)2-BeF2(flibe) Preliminary Vaporization Estimation Using the BUCKY 1-D Radiation Hydrodynamics Code; T.A. Heltemes, E.P. Marriott, G.A. Moses, R.R. Peterson, September 2005 [presented at the 21st IEEE/NPSS Symposium on Fusion Engineering (SOFE), 26-29 September 2005, Knoxville TN]. (7 pages, 1.1 MB) [more]

retrieve PDF Z-Pinch (LiF)2-BeF2(flibe) Preliminary Vaporization Estimation Using the BUCKY 1-D Radiation Hydrodynamics Code; T.A. Heltemes, E.P. Marriott, G.A. Moses, R.R. Peterson, September 2005 [presented at the 21st IEEE/NPSS Symposium on Fusion Engineering (SOFE), 26-29 September 2005, Knoxville TN]. (8 pages, 1.1 MB)

Results: 41 to 43 of 43 order by: UWFDM Author TitleDate
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