New dynamical tide constraints from current and future gravitational wave detections of inspiralling neutron stars

TL;DR

Enhanced gravitational wave phase measurements enable detailed neutron star property constraints, including internal composition and superfluid presence, through tidal oscillation analysis in inspiraling neutron star mergers.

Contribution

This work demonstrates that improved phase uncertainty estimates allow for new constraints on neutron star internal properties and rules out certain instability mechanisms using gravitational wave data.

Findings

GW170817 limits orbital energy transfer to <2x10^47 erg

Future detectors will significantly tighten these constraints

Analysis suggests p-g instability is likely inconsequential in observed regimes

Abstract

Previous theoretical works using the pre-merger orbital evolution of coalescing neutron stars to constrain properties of dense nuclear matter assume a gravitational wave phase uncertainty of a few radians, or about a half cycle. However, recent studies of the signal from GW170817 and next generation detector sensitivities indicate actual phase uncertainties at least twenty times better. Using these refined estimates, we show that future observations of nearby sources like GW170817 may be able to reveal neutron star properties beyond just radius and tidal deformability, such as the matter composition and/or presence of a superfluid inside neutron stars, via tidal excitation of g-mode oscillations. Data from GW170817 already limits the amount of orbital energy that is transferred to the neutron star to <2x10^47 erg and the g-mode tidal coupling to Qmode<10^-3 at 50 Hz (5x10^48 erg and 4x10^-3 at 200 Hz), and future observations and detectors will greatly improve upon these constraints. In addition, analysis using general parameterization models that have been applied to the so-called p-g instability show that the instability already appears to be restricted to regimes where the mechanism is likely to be inconsequential; in particular, we show that the number of unstable modes is <<100 at <~100 Hz, and next generation detectors will essentially rule out this mechanism (assuming that the instability remains undetected). Finally, we illustrate that measurements of tidal excitation of r-mode oscillations in nearby rapidly rotating neutron stars are within reach of current detectors and note that even non-detections will limit the inferred inspiralling neutron star spin rate to <20 Hz, which will be useful when determining other parameters such as neutron star mass and tidal deformability.