Title :
Scalable, Hydrodynamic and Radiation-Hydrodynamic Studies of Neutron Stars Mergers
Abstract :
We discuss the high performance computing issues involved in the numerical simulation of binary neutron star mergers and supernovae. These phenomena, which are of great interest to astronomers and physicists, can only be described by modeling the gravitational field of the objects along with the flow of matter and radiation in a self consistent manner. In turn, such models require the solution of the gravitational field equations, Eulerian hydrodynamic equations, and radiation transport equations. This necessitates the use of scalable, high performance computing assets to conduct the simulations. We discuss some of the parallel computing aspects of this challenging task in this paper.
Keywords :
BiCG; Cray T3E; Eulerian; Silicon Graphics Origin 2000; astronomy; astrophysics; binary neutron stars; fluid dynamics; gravitational field; hydrodynamics; iterative methods; linear systems; multidimensions; neutron star; parallel computing; precondition; radiation transport; Astronomy; Astrophysics; Computational modeling; Corporate acquisitions; Equations; Fluid dynamics; High performance computing; Hydrodynamics; Neutrons; Parallel processing; BiCG; Cray T3E; Eulerian; Silicon Graphics Origin 2000; astronomy; astrophysics; binary neutron stars; fluid dynamics; gravitational field; hydrodynamics; iterative methods; linear systems; multidimensions; neutron star; parallel computing; precondition; radiation transport;
Conference_Titel :
Supercomputing, ACM/IEEE 1997 Conference
Print_ISBN :
0-89791-985-8
DOI :
10.1109/SC.1997.10048
