Deriving formulations for numerical computation of binary neutron stars in quasicircular orbits
Abstract
Two relations, the virial relation M ADM=M K and the first law in the form δ M ADM= δ J, should be satisfied by a solution and a sequence of solutions describing binary compact objects in quasiequilibrium circular orbits. Here, M ADM, M K, J, and are the ADM mass, Komar mass, angular momentum, and orbital angular velocity, respectively. δ denotes an Eulerian variation. These two conditions restrict the allowed formulations that we may adopt. First, we derive relations between M ADM and M K and between δ M ADM and δ J for general asymptotically flat spacetimes. Then, to obtain solutions that satisfy the virial relation and sequences of solutions that satisfy the first law at least approximately, we propose a formulation for computation of quasiequilibrium binary neutron stars in general relativity. In contrast to previous approaches in which a part of the Einstein equation is solved, in the new formulation, the full Einstein equation is solved with maximal slicing and in a transverse gauge for the conformal three-metric. Helical symmetry is imposed in the near zone, while in the distant zone, a waveless condition is assumed. We expect the solutions obtained in this formulation to be excellent quasiequilibria as well as initial data for numerical simulations of binary neutron star mergers.
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