Constraining the p-mode--g-mode tidal instability with GW170817

Abstract

We analyze the impact of a proposed tidal instability coupling p-modes and g-modes within neutron stars on GW170817. This non-resonant instability transfers energy from the orbit of the binary to internal modes of the stars, accelerating the gravitational-wave driven inspiral. We model the impact of this instability on the phasing of the gravitational wave signal using three parameters per star: an overall amplitude, a saturation frequency, and a spectral index. Incorporating these additional parameters, we compute the Bayes Factor ( Bpg!pg) comparing our p-g model to a standard one. We find that the observed signal is consistent with waveform models that neglect p-g effects, with Bpg!pg = 0.03+0.70-0.58 (maximum a posteriori and 90% credible region). By injecting simulated signals that do not include p-g effects and recovering them with the p-g model, we show that there is a 50\% probability of obtaining similar Bpg!pg even when p-g effects are absent. We find that the p-g amplitude for 1.4 M neutron stars is constrained to few×10-7, with maxima a posteriori near 10-7 and p-g saturation frequency 70\, Hz. This suggests that there are less than a few hundred excited modes, assuming they all saturate by wave breaking. For comparison, theoretical upper bounds suggest a p-g amplitude 10-6 and 103 modes saturating by wave breaking. Thus, the measured constraints only rule out extreme values of the p-g parameters. They also imply that the instability dissipates 1051\, ergs over the entire inspiral, i.e., less than a few percent of the energy radiated as gravitational waves.