The equation of state and some key parameters of neutron stars: constraints from GW170817, the nuclear data and the low mass X-ray binary data

Abstract

In this work we parameterize the Equation of State of dense neutron star (NS) matter with four pressure parameters of \p1, p2, p3, p4\ and then set the combined constraints with the data of GW 170817 and the data of 6 Low Mass X-ray Binaries (LMXBs) with thermonuclear burst or alternatively the symmetry energy of the nuclear interaction. We find that the nuclear data effectively narrow down the possible range of p1, the gravitational wave data plays the leading role in bounding p2, and the LMXB data as well as the lower bound on maximal gravitational mass of non-rotating NSs govern the constraints on p3 and p4. Using posterior samples of pressure parameters and some universal relations, we further investigate how the current data sets can advance our understanding of tidal deformability (), moment of inertia (I) and binding energy (BE) of NSs. For a canonical mass of 1.4M, we have I1.4 = 1.43+0.30-0.13 × 1038~ kg · m2, 1.4 = 390-210+280 , R1.4 = 11.8-0.7+1.2~ km and BE1.4 = 0.16+0.01-0.02 M if the constraints from the nuclear data and the gravitational wave data have been jointly applied. For the joint analysis of gravitational wave data and the LMXB data, we have I1.4 = 1.28+0.15-0.08 × 1038~ kg · m2, 1.4 = 220-90+90, R1.4 = 11.1-0.6+0.7~ km and BE1.4 = 0.18+0.01-0.01 M. These results suggest that the current constraints on and R still suffer from significant systematic uncertainties, while I1.4 and BE1.4 are better constrained.