Abstract:
For the self-gravitating gas dynamics simulation, an explicit multi-step
algorithm is proposed. A spatial three-dimensional programming code on a
Cartesian grid in the Euler variables was developed using the
Fluid-in-Cell method. The numerical algorithm has the first-order
approximation. The corresponding grid viscosity provides the stability of
numerical solutions. Computations for a sequence of grid refinements show
the convergence of the algorithm. Results of isothermal collapse
simulation, isentropic self-gravitating gas rotations, and its self-similar
expansion are discussed.
The work was supported by the RAS Presidium Program “The Origin, Structure
and Evolution of Objects in the Universe”, the RAS Presidium Program
“The Origin of the Biosphere and Geo-Biological Evolution”, and the SB RAS
Integration Project No. 26 “Mathematical Models, Numerical Methods and
Parallel Algorithms for Solving Large Problems of SB RAS and Their
Implementation on Multiprocessor Supercomputers”. The computations were
performed at the Siberian Supercomputer Center using a common memory
computer SMP16x256.
Keywords:splitting methods; large-particle method; gravitational gas dynamics.
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