A microscopic estimate of the nuclear matter compressibility and symmetry energy in relativistic mean-field models

Abstract

The relativistic mean-field plus RPA calculations, based on effective Lagrangians with density-dependent meson-nucleon vertex functions, are employed in a microscopic analysis of the nuclear matter compressibility and symmetry energy. We compute the isoscalar monopole and the isovector dipole response of 208Pb, as well as the differences between the neutron and proton radii for 208Pb and several Sn isotopes. The comparison of the calculated excitation energies with the experimental data on the giant monopole resonance in 208Pb, restricts the nuclear matter compression modulus of structure models based on the relativistic mean-field approximation to K nm≈ 250 - 270 MeV. The isovector giant dipole resonance in 208Pb, and the available data on differences between neutron and proton radii, limit the range of the nuclear matter symmetry energy at saturation (volume asymmetry) to 32 MeV ≤ a4 ≤ 36 MeV.

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