Correlations between the nuclear matter symmetry energy, its slope, and curvature from a nonrelativistic solvable approach and beyond

Abstract

By using point-coupling versions of finite range nuclear relativistic mean field models containing cubic and quartic self interactions in the scalar field σ, a nonrelativistic limit is achieved. This approach allows an analytical expression for the symmetry energy (J) as a function of its slope (L) in a unified form, namely, \,L\,=\,3J\,+f(m*,o,Bo,Ko), where the quantities m*, o, Bo and Ko are bulk parameters at the nuclear matter saturation density o. This result establishes a linear correlation between L and J which is reinforced by exact relativistic calculations. An analogous analytical correlation is also found for J, L and the symmetry energy curvature (Ksym). Based on these results, we propose graphic constraints in L× J and Ksym× L planes which finite range models must satisfy.