Pairing and nonaxial-shape correlations in N=150 isotones

Abstract

Background: The Kπ=2- excited band emerges systematically in N=150 isotones raging from Pu to No with even-Z numbers, and a sharp drop in energies was observed in Cf. Purpose: I attempt to uncover the microscopic mechanism for the appearance of such a low-energy 2- state in 248Cf. Furthermore, I investigate the possible occurrence of the low-energy Kπ=2+ state to elucidate the mechanism that prefers the simultaneous breaking of the reflection and axial symmetry to the breaking of the axial symmetry alone in this mass region. Method: I employ a nuclear EDF method: the Skyrme-Kohn-Sham-Bogoliubov and the quasiparticle random-phase approximation are used to describe the ground state and the transition to excited states. Results: The Skyrme-type SkM* and SLy4 functionals reproduce the fall in energy, but not the absolute value, of the Kπ=2- state at Z=98, where the proton 2qp excitation [633]7/2 [521]3/2 plays a decisive role for the peculiar isotonic dependence. I find interweaving roles by the pairing correlation of protons and the deformed shell closure at Z=98. The SkM* model predicts the Kπ=2- state appears lower in energy in 246Cf than in 248Cf as the Fermi level of neutrons is located in between the [622]5/2 and [734]9/2 orbitals. Except for 250Fm in the SkM* calculation, the Kπ=2+ state is predicted to appear higher in energy than the Kπ=2- state because the quasi-proton [521]1/2 orbital is located above the [633]7/2 orbital. Conclusions: A systematic study of low-lying collective states in heavy actinide nuclei provides a rigorous testing ground for microscopic nuclear models. The present study shows a need for improvements in the EDFs to describe pairing correlations and shell structures in heavy nuclei, that are indispensable in predicting the heaviest nuclei.