Shape and multiple shape coexistence of nuclei within covariant density functional theory

Shape and multiple shape coexistence of nuclei are investigated throughout the nuclear chart by calculating the low-lying spectra and the quadrupole shape invariants for even-even nuclei with 10 Z 104 from the proton drip line to the neutron one within a five-dimensional collective Hamiltonian based on the covariant density functional PC-PK1. The quadrupole shape invariants are implemented to characterize the quadrupole deformations of low-lying 0+ states and predict nuclear mass regions of shape and multiple shape coexistence. The predicted low-lying spectra and the shape or multishape coexisting nuclei are overall in good agreement with the available experimental results. In addition, the present work predicts a wealth of nuclei with shape or multiple shape coexistence in the neutron-rich regions. The connection between the strong E0 transition strength and the occurrence of shape coexistence is analyzed systemically. It is found that nuclei with pronounced shape coexistence generally have strong E0 transition strengths, while the reverse may not be true. The present results can serve as useful guidelines for experimental searches and theoretical studies of shape and multiple shape coexistence, especially in neutron-rich regions.

Automated summary

The study investigates the shape and multiple shape coexistence of nuclei by calculating low-lying spectra and quadrupole shape invariants. The results predict nuclear mass regions where shape and multiple shape coexistence occur and are in agreement with experimental data. The study also predicts the occurrence of shape or multiple shape coexistence in neutron-rich regions. The connection between strong E0 transition strength and shape coexistence is analyzed, indicating that nuclei with pronounced shape coexistence generally have strong E0 transition strengths.