A set of hadronic equations of state (EoSs) derived from relativistic density-functional theory and constrained by terrestrial experiments, astrophysical observations, in particular by the GW170817 event, and chiral effective field theory (chi EFT) of neutron matter is used to explore the sensitivity of the EoS parameterization on the few nuclear-matter characteristics defined at the saturation density. We find that the gross properties of compact stars are most sensitive to the isoscalar skewness coefficient Q(sat) and the isovector slope coefficient L-sym around saturation density, since the higher-order coefficients, such as K-sym, are fixed by our model. More specifically, (i) among these Q(sat) is the dominant parameter controlling both the maximum mass and the radii of compact stars while Lsym is constrained somewhat by chi EFT of neutron matter, (ii) massive-enough (M similar to 2.0M(circle dot)) compact stars featuring both hyperons and Delta resonances can be obtained if the value of Q(sat) is large enough, and (iii) the emergence of Delta's reduces the radius of a canonical mass (M similar to 1.4M(circle dot)) compact star thus easing the tension between the predictions of the relativistic density functionals and the inferences from the x-ray observation of nearby isolated neutron stars.
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