Nuclear matter symmetry energy and the symmetry energy coefficient in the mass formula

Abstract

Within the Skyrme-Hartree-Fock (SHF) approach, we show that for a fixed mass number A, both the symmetry energy coefficient asym(A) in the semi-empirical mass formula and the nuclear matter symmetry energy Esym(A) at a subsaturation reference density rhoA can be determined essentially by the symmetry energy Esym(rho0) and its density slope L at saturation density rho0. Meanwhile, we find the dependence of asym(A) on Esym(rho0) or L is approximately linear and is very similar to the corresponding linear dependence displayed by Esym(A), providing an explanation for the relation Esym(A) ≈ asym(A). Our results indicate that a value of Esym(A) leads to a linear correlation between Esym(rho0) and L and thus can put important constraints on Esym(rho0) and L. Particularly, the values of Esym(rho0)= 30.5 +- 3 MeV and L= 52.5 +- 20 MeV are simultaneously obtained by combining the constraints from recently extracted Esym(A=0.1 fm-3) with those from recent analyses of neutron skin thickness of Sn isotopes in the same SHF approach.