James M. Lattimer
Published 2023-08-15Version 1
Nuclear mass measurements and neutron matter theory tightly constrain the nuclear symmetry energy parameters $J$, $L$, $K_{sym}$ and $Q_{sym}$. Corroboration of these constraints on $J$ and $L$ can be found from measurements of the neutron skin thicknesses and dipole polarizabilities of neutron-rich nuclei. The experimental constraints on these parameters are compared with those obtained from consideration of astrophysical measurements of the neutron star radius, which we show is highly correlated with $L$. Attention is aimed at the recent PREX and CREX neutron skin measurements from Jefferson Lab, NICER neutron star radius measurements, and a new interpretation of the GW170817 tidal deformability measurement. We find joint satisfaction of PREX and CREX gives $J=32.2\pm1.7$ MeV and $L=52.9\pm13.2$ MeV, in excellent agreement with neutron matter predictions of $J=32.0\pm1.1$ MeV and $L=51.9\pm7.9$ MeV.
Comments: Compact Stars in the QCD Phase Diagram (CSQCD) IX, Banff, Canada, 2022. arXiv admin note: substantial text overlap with arXiv:2301.03666
Journal: Journal of Physics: Conference Series, Volume 2536, Issue 1, id.012009, 10 pp. (2023)
Constraints on Nuclear Symmetry Energy Parameters
GW170817, PSR J0030+0451, and PSR J0740+6620: constraints on phase transition and nuclear symmetry energy parameters
Unveiling the correlations of tidal deformability with the nuclear symmetry energy parameters
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