Systematic study of the symmetry energy coefficient in finite nuclei

Abstract

The symmetry energy coefficients in finite nuclei have been studied systematically with a covariant density functional theory (DFT) and compared with the values calculated using several available mass tables. Due to the contamination of shell effect, the nuclear symmetry energy coefficients extracted from the binding energies have large fluctuations around the nuclei with double magic numbers. The size of this contamination is shown to be smaller for the nuclei with larger isospin value. After subtracting the shell effect with the Strutinsky method, the obtained nuclear symmetry energy coefficients with different isospin values are shown to decrease smoothly with the mass number A and are subsequently fitted to the relation 4a symA=bvA-bsA4/3. The resultant volume bv and surface bs coefficients from axially deformed covariant DFT calculations are 121.73 and 197.98 MeV respectively. The ratio bs/bv=1.63 is in good agreement with the value derived from the previous calculations with the non-relativistic Skyrme energy functionals. The coefficients bv and bs corresponding to several available mass tables are also extracted. It is shown that there is a strong linear correlation between the volume bv and surface bs coefficients and the ratios bs/bv are in between 1.6-2.0 for all the cases.