Which Neutron Stars Reach the Stiffening Regime? Multimessenger Constraints on Core Sound Speed and Stellar-Mass Thresholds

Abstract

We present a concise multimessenger inference of the neutron-star core sound-speed profile using GW170817 and three NICER mass--radius posteriors (PSR J0030+0451, PSR J0740+6620, and PSR J0437-4715). The main result is not only a preference for intermediate-density stiffening within smooth equation-of-state families, but a translation of that inference into the stellar masses that access the relevant density regime. In the baseline smooth peaked family, the posterior probability that cs2 > 1/3 at 3.5\,n sat is 85.4\,\%, while equal-prior averaging over peaked, monotonic, piecewise, and transition-capable families gives a more conservative 79.0\,\%. Posterior-resampled exact Tolman--Oppenheimer--Volkoff solutions show that the onset density of the inferred stiffening is typically reached near 1.6\,M, whereas the peak region is accessed only near 2.1\,M. A J0740-like 2.07\,M pulsar reaches the onset in 91\,\% of posterior draws but the peak in only 46\,\%, showing that current data mainly constrain whether massive stars have entered the stiffening regime rather than traversed its full peak.