Abstract
Determining the equation of state of matter at nuclear density and hence the structure of neutron stars has been a riddle for decades. We show how the imminent detection of gravitational waves from merging neutron star binaries can be used to solve this riddle. Using a large number of accurate numerical-relativity simulations of binaries with nuclear equations of state, we have found that the postmerger emission is characterized by two distinct and robust spectral features. While the high-frequency peak has already been associated with the oscillations of the hypermassive neutron star produced by the merger and depends on the equation of state, a new correlation emerges between the low-frequency peak, related to the merger process, and the compactness of the progenitor stars. More importantly, such a correlation is essentially universal, thus providing a powerful tool to set tight constraints on the equation of state. If the mass of the binary is known from the inspiral signal, the combined use of the two frequency peaks sets four simultaneous constraints to be satisfied. Ideally, even a single detection would be sufficient to select one equation of state over the others. We have tested our approach with simulated data and verified it works well for all the equations of state considered.
Highlights
This decade is likely to witness the first direct detection of gravitational waves (GWs) as a series of advanced detectors such as LIGO [1], Virgo [2], and KAGRA [3] become operational in the five years
A second signature is instead related to the postmerger phase, where the object formed by the merger [most likely a hypermassive neutron star (HMNS)] can emit GWs in a narrow frequency range before collapsing to a black hole [10]
As discussed by several authors [10,11,12,13,14, 31], the power spectral density (PSD) of the postmerger GW signal exhibits a number of clear peaks
Summary
While the high-frequency peak has already been associated with the oscillations of the hypermassive neutron star produced by the merger and depends on the equation of state, a new correlation emerges between the low-frequency peak, related to the merger process, and the total compactness of the stars in the binary. Such a correlation is essentially universal, providing a powerful tool to set tight constraints on the equation of state. PACS numbers: 04.25.Dm, 04.25.dk, 04.30.Db, 04.40.Dg, 95.30.Lz, 95.30.Sf, 97.60.Jd arXiv:1403.5672v2 [gr-qc] 21 Aug 2014
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