FTI Research
- APEX
- ARIES
- Code Development
- D-3He Fuel Cycle
- Environmental Impact
- FIRE
- FRC
- HAPL
- IEC
- ITER
- Liquid Metal Safety
- Lunar Mining
- Medical Isotopes
- RadHydro
- Shock Tube
- Space Propulsion
- X1 Chamber
MFE & IFE Studies UW Neutronics Center of Excellence Inertial Electrostatic Confinement Shock Tube
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.Related Links
- Simulation of Inertial Confinement Fusion at UW (pdf poster)
FTI Publications
Improving Implicit Non-local Electron Transport in 2D DRACO Simulations; D. Cao, J. Chenhall, G. Moses, J. Delettrez, T. Collins, November 2013 [presented at the 55th Annual Meeting of the APS Division of Plasma Physics, 11-15 November 2013, Denver CO]. (1 page, 436 kB) [more]
Double P1 Approximation to Electron Distribution Function for Purposes of Computing Non-Local Electron Transport; Jeffrey Chenhall, Duc Cao, Gregory Moses, November 2013 [presented at the 55th Annual Meeting of the APS Division of Plasma Physics, 11-15 November 2013, Denver CO]. (1 page, 989 kB)
Radiation Hydrodynamic Simulations of the Inertial Fusion Energy Reactor Chamber; Ryan Sacks and Gregory Moses, March 2014. (1 page, 1.1 MB)