Incompressibility in finite nuclei and nuclear matter

Abstract

The incompressibility (compression modulus) K 0 of infinite symmetric nuclear matter at saturation density has become one of the major constraints on mean-field models of nuclear many-body systems as well as of models of high density matter in astrophysical objects and heavy-ion collisions. We present a comprehensive re-analysis of recent data on GMR energies in even-even 112-124Sn and 106,100-116Cd and earlier data on 58 A 208 nuclei. The incompressibility of finite nuclei K A is expressed as a leptodermous expansion with volume, surface, isospin and Coulomb coefficients K vol, K surf, Kτ and K coul. Assuming that the volume coefficient K vol is identified with K 0, the K coul = -(5.2 0.7) MeV and the contribution from the curvature term K curvA -2/3 in the expansion is neglected, compelling evidence is found for K 0 to be in the range 250 < K 0 < 315 MeV, the ratio of the surface and volume coefficients c = K surf/K vol to be between -2.4 and -1.6 and K τ between -840 and -350 MeV. We show that the generally accepted value of K 0 = (240 20) MeV can be obtained from the fits provided c -1, as predicted by the majority of mean-field models. However, the fits are significantly improved if c is allowed to vary, leading to a range of K 0, extended to higher values. A self-consistent simple (toy) model has been developed, which shows that the density dependence of the surface diffuseness of a vibrating nucleus plays a major role in determination of the ratio K surf/K vol and yields predictions consistent with our findings.