Potential signature of new magicity from universal aspects of nuclear charge radii

Abstract

Shell quenching phenomena in nuclear charge radii are typically observed at the well-established neutron magic numbers. However, the recent discovery of potential new magic numbers at the neutron numbers N = 32 and N = 34 has sparked renewed interest in this mass region. This work further inspects into the charge radii of nuclei around the N = 28 shell closure using the relativistic Hartree-Bogoliubov model. We incorporate meson exchange and point-coupling effective nucleon-nucleon interactions alongside the Bogoliubov transformation for pairing corrections. To accurately capture the odd-even staggering and shell closure effects observed in charge radii, neutron-proton correlations around Fermi surface are explicitly considered. The charge radii of Ca and Ni isotopes are used to test the theoretical model and show an improvement with neutron-proton pairing corrections, in particular for neutron-rich isotopes. Our calculations reveal a inverted parabolic-like trend in the charge radii along the N = 28 isotones for proton numbers Z between 20 and 28. Additionally, the shell closure effect of Z = 28 persists across the N = 28, 30, 32, and 34 isotonic chains, albeit with a gradual weakening trend. Notably, the significantly abrupt changes in charge radii are observed across Z = 22 along both the N = 32 and N = 34 isotonic chains. This kink at Z = 22 comes from the sudden decrease of the neuron-proton correlation around Fermi surfaces across Z = 22 for N = 30, 32, and 34 isotones, and might provide a signature for identifying the emergence of neutron magic numbers N = 32 and 34. Furthermore, the calculated charge radii for these isotonic chains (N = 28, 30, 32, and 34) can serve as reliable guidelines for future experimental measurements.

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