Gravitational wave asteroseismology of neutron stars with unified EOS: on the role of high-order nuclear empirical parameters

Abstract

We analyze the sensitivity of non-radial fluid oscillation modes and tidal deformations in neutron stars to high-order nuclear empirical parameters (NEP). In particular, we study the impact of the curvature and skewness of the symmetry energy K sym, Q sym, and the skewness of the binding energy in symmetric nuclear matter Q sat. As we are interested in the possibility of gravitational wave detection by future interferometers, we consider that the tidal interaction is the driving force for the quadrupolar non-radial fluid oscillations. We have also studied the correlations between those quantities, which will be useful to understand the strong physics of gravitational wave phenomena. Our main results show that K sym impacts the frequencies of the fundamental mode mainly for low-mass neutron stars. The NEP Q sym and Q sat affect the fundamental modes of intermediate and heavy neutron stars, respectively. In the case of the first pressure mode, K sym shows a small effect, while Q sat shows a considerable decrease in this oscillation mode independent of the neutron star mass. Similarly, for tidal deformability, the NEP Q sat and Q sym show a bigger impact than K sym. Given the impact of the NEP on gravitational wave phenomena and the currently large uncertainties of these parameters, the prospect of higher sensitivity in future gravitational wave detectors promise a possible new tool to constrain high-order NEP.

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