Cone-Guided Fast Ignition with no Imposed Magnetic Fields
Abstract
Simulations of ignition-scale fast ignition targets have been performed with the new integrated Zuma-Hydra PIC-hydrodynamic capability. We consider an idealized spherical DT fuel assembly with a carbon cone, and an artificially-collimated fast electron source. We study the role of E and B fields and the fast electron energy spectrum. For mono-energetic 1.5 MeV fast electrons, without E and B fields, the energy needed for ignition is E_f^{ig} = 30 kJ. This is about 3.5x the minimal deposited ignition energy of 8.7 kJ for our fuel density of 450 g/cm^3. Including E and B fields with the resistive Ohm's law E = \eta J_b gives E_f^{ig} = 20 kJ, while using the full Ohm's law gives E_f^{ig} > 40 kJ. This is due to magnetic self-guiding in the former case, and \nabla n \times \nabla T magnetic fields in the latter. Using a realistic, quasi two-temperature energy spectrum derived from PIC laser-plasma simulations increases E_f^{ig} to (102, 81, 162) kJ for (no E/B, E = \eta J_b, full Ohm's law). This stems from the electrons being too energetic to fully stop in the optimal hot spot depth.
Cite
@article{arxiv.1111.5089,
title = {Cone-Guided Fast Ignition with no Imposed Magnetic Fields},
author = {D. J. Strozzi and M. Tabak and D. J. Larson and M. M. Marinak and M. H. Key and L. Divol and A. J. Kemp and C. Bellei and H. D. Shay},
journal= {arXiv preprint arXiv:1111.5089},
year = {2012}
}
Comments
Minor revisions in response to referee comments