Beyond-mean-field description of octupolarity in dysprosium isotopes with the Gogny-D1M energy density functional

Abstract

The emergence and stability of (static) octupole deformation effects in Dy isotopes from dripline to dripline (72 N 142) is analyzed in this paper using mean-field and beyond-mean-field techniques often used for this purpose. We find static octupole deformations at the Hartree-Fock-Bogoliubov (HFB) level with the Gogny D1M force for N ≈ 134 isotopes, while nuclei with N ≈ 88 exhibit reflection-symmetric ground states. It is shown that, given the softness found in the mean-field and parity-projected potential energy surfaces along the octupole direction, neither of these two levels of approximation is suficcient to extract conclusions about the (permanent and/or vibrational) nature of octupole dynamic in Dy isotopes. From the analysis of the collective wave functions as well as the excitation energies of the first negative-parity states and B(E3) strengths, obtained within the framework of a two-dimensional symmetry-conserving generator coordinate method (2D-GCM), it is concluded that the increased octupole collectivity in Dy isotopes with N ≈ 88 and N ≈ 134 is a vibrational-like effect that is not directly related to permanent mean-field octupole deformation in the considered nuclei. A pronounced suppression of the B(E1) strengths is predicted for isotopes with N ≈ 82 and N ≈ 126. The comparison of results obtained with other parametrizations, show the robustness of the predicted trends with respect to the underlying Gogny energy density functional.