Dynamical tides in neutron stars with first-order phase transitions: the role of the discontinuity mode
Abstract
During the late stages of a binary neutron star inspiral, dynamical tides induced in each star by its companion become significant and should be included in complete gravitational-wave (GW) modeling. We investigate the coupling between the tidal field and quasi-normal modes in hybrid stars and show that the discontinuity mode (g-mode) - intrinsically associated with first-order phase transitions and buoyancy - contributes non-negligibly compared with the fundamental f-mode. We find that the g-mode overlap integral can reach up to 10\% of the f-mode value for hybrid star masses in the range 1.4-2.0M, with the largest values generally associated with larger density jumps. This leads to a GW phase shift due to the g-mode of φg 0.1-1 rad (i.e., up to 5\%-10\% of φf), with the largest shifts occurring for masses near the phase transition. At higher masses, the shifts remain smaller and nearly constant, with φg 0.1 rad (roughly 1\% of φf). These GW shifts may be relevant even at the design sensitivity of current second-generation GW detectors in the most optimistic cases. Moreover, if a g-mode is present and lies near the f-mode frequency, neglecting it in the GW modeling can lead to systematic biases in neutron star parameter estimation, resulting in radius errors of up to 1\%-2\%. These results show the importance of dynamical tides to probe neutron stars' equation of state, and to test the existence of dense-matter phase transitions.
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