Impact of nonlinearities on relativistic dynamical tides in compact binary inspirals

Abstract

The tidal deformation of a neutron star in a binary inspiral driven by the emission of gravitational waves affects the orbital dynamics and produces a measurable modulation of the waves. Late in the inspiral, a regime of dynamical tides takes over from a prior regime of static tides. A recent analysis by Yu et al. [M.N.R.A.S. 519, 4325 (2022)] reveals that nonlinear aspects of the tidal interaction are important during the regime of dynamical tides. Their theoretical framework is grounded in Newtonian gravity and fluid mechanics, and relies on a representation of the tidal deformation in terms of the star's normal modes of vibration. We confirm their observation in a general relativistic treatment of the tidal deformation of a neutron star, without relying on a mode representation of this deformation. The starting point of our description is a simultaneous time-derivative and nonlinear expansion of the tidal deformation, expressed in terms of three encapsulating constants, the static k2, dynamic k2, and nonlinear p2 tidal constants. We describe the neutron star's deformation in terms of a well-defined quadrupole moment tensor, which is related to the tidal quadrupole moment through a frequency-domain response function k2(ω). In a pragmatic extension of our simultaneous expansion, we express this in a form proportional to (1-ω2/ω*2)-1, the characteristic response of a harmonic oscillator subjected to a driving force of frequency ω, with a natural-frequency parameter ω* constructed from the tidal constants. We compute these for polytropic stellar models, and show that the nonlinear constant p2 lowers the frequency parameter by as much as 15% relative to an estimation based on a purely linear treatment of the tidal deformation.