Code O-SUKI: Simulation of direct-drive fuel target implosion in heavy ion inertial fusion

@article{Sato2019CodeOS,
  title={Code O-SUKI: Simulation of direct-drive fuel target implosion in heavy ion inertial fusion},
  author={R. Sato and Shigeo Kawata and Takahiro Karino and Kenji Uchibori and T. Iinuma and Hiroaki Katoh and A. I. Ogoyski},
  journal={Comput. Phys. Commun.},
  year={2019},
  volume={240},
  pages={83-100}
}
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8 Citations
Background Citations
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Methods Citations
3

8 Citations

Citation Type

Citation Type

Development of fuel target implosion simulation system in heavy ion inertial confinement fusion
Uniformity improvement of fuel target implosion by phase control in heavy ion inertial fusion
Non-uniformity smoothing of direct-driven fuel target implosion by phase control in heavy ion inertial fusion
TLDR
The dynamic smoothing method is applied to a spherical direct-driven fuel target implosion in heavy ion inertial confinement fusion and it is found that the wobbling motion of each heavy ion beam (HIB) axis induces a phase- controlled HIBs energy deposition, and consequently the phase-controlled implosion acceleration is realized, so that the Hibs irradiation non-uniformity is successfully smoothed.
Direct-drive heavy ion beam inertial confinement fusion: a review, toward our future energy source
ABSTRACT Direct-drive heavy ion beam (HIB) inertial confinement fusion (ICF), or HIF would be a promising future energy source for society. Particle accelerators produce HIBs with precise particle
Three-Dimensional Euler Fluid Code for Fusion Fuel Ignition and Burning
The document describes a numerical algorithm to simulate plasmas and fluids in the 3 dimensional space by the Euler method, in which the spatial meshes are fixed to the space. The plasmas and fluids
Recent progress for different inertial confinement fusion schemes: a systematical review
The pursuing of controlled fusion energy has been continuously developed for more than half a century. Inertial confinement fusion (ICF) is one of two major approaches to actualize controlled fusion.
3-Dimensional Lagrange Code for Metal (Gold) Cone Plasma
The document describes a numerical algorithm for plasms and fluids by the Lagrange method, in which the spatial meshes follow the plasma and fluid behavior. Through the mesh wall the plasma and the
Code O-SUKI-N 3D: Upgraded direct-drive fuel target 3D implosion code in heavy ion inertial fusion

References

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The radiation transport effect on pellet implosion and the Rayleigh-Taylor (R-T) instability are studied in a light-ion beam (LIB) inertial confinement fusion (ICF) by numerical simulation and
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