Constraints on neutron skin thickness in 208Pb and density-dependent symmetry energy

Abstract

Accurate knowledge about the neutron skin thickness Rnp in 208Pb has far-reaching implications for different communities of nuclear physics and astrophysics. Yet, the novel Lead Radius Experiment (PREX) did not yield stringent constraint on the Rnp recently. We employ a more practicable strategy currently to probe the neutron skin thickness of 208Pb based on a high linear correlation between the Rnp and J-asym, where J and asym are the symmetry energy (coefficient) of nuclear matter at saturation density and of 208Pb. An accurate J-asym thus places a strong constraint on the Rnp. Compared with the parity-violating asymmetry APV in the PREX, the reliably experimental information on the J-asym is much more easily available attributed to a wealth of measured data on nuclear masses and on decay energies. The density dependence of the symmetry energy is also well constrained with the J-asym. Finally, with a `tomoscan' method, we find that one just needs to measure the nucleon densities in 208Pb starting from Rm = 7.610.04 fm to obtain the Rnp in hadron scattering experiments, regardless of its interior profile that is hampered by the strong absorption.