Pedro Marronetti
Published 2005-01-12, updated 2005-05-01Version 2
Due to the complexity of the required numerical codes, many of the new formulations for the evolution of the gravitational fields in numerical relativity are not tested on binary evolutions. We introduce in this paper a new testing ground for numerical methods based on the simulation of binary neutron stars. This numerical setup is used to develop a new technique, the Hamiltonian relaxation (HR), that is benchmarked against the currently most stable simulations based on the BSSN method. We show that, while the length of the HR run is somewhat shorter than the equivalent BSSN simulation, the HR technique improves the overall quality of the simulation, not only regarding the satisfaction of the Hamiltonian constraint, but also the behavior of the total angular momentum of the binary. The latest quantity agrees well with post-Newtonian estimations for point-mass binaries in circular orbits.
Comments: More detailed description of the numerical implementation added and some typos corrected. Version accepted for publication in Class. and Quantum Gravity
Journal: Class.Quant.Grav.22:2433-2451,2005
Relativistic Models for Binary Neutron Stars with Arbitrary Spins
Various features of quasiequilibrium sequences of binary neutron stars in general relativity
Beyond second-order convergence in simulations of binary neutron stars in full general-relativity
