Black hole-neutron star binary merger: Dependence on black hole spin orientation and equations of state

Abstract

We systematically performed numerical-relativity simulations for black hole (BH) - neutron star (NS) binary mergers with a variety of the BH spin orientation and equations of state (EOS) of the NS. The initial misalignment angles of the BH spin are chosen in the range of itilt,0 = 30--90[deg.]. We employed four models of NS EOS with which the compactness of the NS is in the range of C = MNS/RNS = 0.138--0.180, where MNS and RNS are the mass and the radius of the NS, respectively. The mass ratio of the BH to the NS, Q = MBH/MNS, and the dimensionless spin parameter of the BH, chi, are chosen to be Q = 5 and chi = 0.75, together with MNS = 1.35 Msun. We obtain the following results: (i) The inclination angle of itilt,0 < 70[deg.] and itilt,0 < 50[deg.] are required for the formation of a remnant disk with its mass larger than 0.1 Msun for the case C = 0.140 and C = 0.160, respectively, while the disk mass is always smaller than 0.1Msun for C = 0.175. The ejecta with its mass larger than 0.01 Msun is obtained for itilt,0 < 85[deg.] with C = 0.140, for itilt,0 < 65[deg.] with C = 0.160, and for itilt,0 < 30[deg.] with C = 0.175. (ii) The rotational axis of the dense part of the remnant disk is approximately aligned with the remnant BH spin for itilt,0 = 30[deg.]. On the other hand, the disk axis is misaligned initially with ~ 30[deg.] for itilt,0 = 60[deg.], and the alignment with the remnant BH spin is achieved at ~ 50--60 ms after the onset of merger. The accretion time scale of the remnant disk is typically ~ 100 ms and depends only weakly on the misalignment angle and the EOS. (iii) The ejecta velocity is typically ~ 0.2--0.3c and depends only weakly on itilt,0 and the EOS of the NS, while the morphology of the ejecta depends on its mass. (iv) The gravitational-wave spectra contains the information of the NS compactness in the cutoff frequency for itilt,0 < 60[deg.].