Tidal Resonance in Binary Neutron Star Inspirals: A High-Precision Study in Numerical Relativity
Abstract
We investigate the tidal resonance of the fundamental (f-)mode in spinning neutron stars, robustly tracing the onset of the excitation to its saturation, using numerical relativity for the first time. We performed long-term (≈15~orbits) fully relativistic simulations of a merger of two highly and retrogradely spinning neutron stars. The resonance window of the f-mode is extended by self-interaction, and the nonlinear resonance continues up to the final plunging phase. We observe that the quasi-circular orbit is maintained throughout since the dissipation of orbit motion due to the resonance is coherent with that due to gravitational waves. The f-mode resonance causes a variation in the stellar spin of 6.3\% in the linear regime and much more as 33\% during the later nonlinear regime. At the merger, a phase shift of 40~radians is rendered in the gravitational waveform as a consequence of the angular momentum and energy transfers into the neutron star oscillations.
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