Plausible presence of new state in neutron stars with masses above 0.98M TOV

Abstract

We investigate the neutron star (NS) equation of state (EOS) by incorporating multi-messenger data of GW170817, PSR J0030+0451, PSR J0740+6620, and state-of-the-art theoretical progresses, including the information from chiral effective field theory () and perturbative quantum chromodynamics (pQCD) calculation. Taking advantage of the various structures sampling by a single-layer feed-forward neural network model embedded in the Bayesian nonparametric inference, the structure of NS matter's sound speed c s is explored in a model-agnostic way. It is found that a peak structure is common in the c s2 posterior, locating at 2.4-4.8 sat (nuclear saturation density) and c s2 exceeds c2/3 at 90\% credibility. The non-monotonic behavior suggests evidence of the state deviating from hadronic matter inside the very massive NSs. Assuming the new/exotic state is featured as it is softer than typical hadronic models or even with hyperons, we find that a sizable (≥ 10-3M) exotic core, likely made of quark matter, is plausible for the NS with a gravitational mass above about 0.98M TOV, where M TOV represents the maximum gravitational mass of a non-rotating cold NS. The inferred M TOV = 2.18+0.27-0.13M (90\% credibility) is well consistent with the value of 2.17+0.15-0.12M estimated independently with GW170817/GRB 170817A/AT2017gfo assuming a temporary supramassive NS remnant formed after the merger. PSR J0740+6620, the most massive NS detected so far, may host an exotic core with a probability of ≈ 0.36.

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