Differential analysis of incompressibility in neutron-rich nuclei

Abstract

Both the incompressibility of a finite nucleus of mass A and that (K∞) of infinite nuclear matter are fundamentally important for many critical issues in nuclear physics and astrophysics. While some consensus has been reached about the K∞, accurate theoretical predictions and experimental extractions of Kτ characterizing the isospin dependence of have been very difficult. We propose a differential approach to extract the and independently from the data of any two nuclei in a given isotope chain. Applying this new method to the data from isoscalar giant monopole resonances (ISGMR) in even-even Pb, Sn, Cd and Ca isotopes taken by U. Garg et al. at the Research Center for Nuclear Physics (RCNP), Osaka University, Japan, we find that the 106Cd-116Cd and 112Sn-124Sn pairs having the largest differences in isospin asymmetries in their respective isotope chains measured so far provide consistently the most accurate up-to-date value of Kτ=-616 59 MeV and Kτ=-623 86 MeV, respectively, largely independent of the remaining uncertainties of the surface and Coulomb terms in expanding the K A, while the K∞ values extracted from different isotopes chains are all well within the current uncertainty range of the community consensus for K∞. Moreover, the size and origin of the "Soft Sn Puzzle" is studied with respect to the "Stiff Pb Phenomenon". It is found that the latter is favored due to a much larger (by 380 MeV) for Pb isotopes than for Sn isotopes, while the from analyzing the data of Sn isotopes is only about 5 MeV less than that from analyzing the Pb data.