Quadrupole-hexadecapole correlations in neutron-rich samarium and gadolinium isotopes
Abstract
We present an extensive study of quadrupole-hexadecapole correlation effects in even-even Sm and Gd isotopes with neutron number N=88-106. The calculations are performed in the framework of the Gogny energy density functional (EDF) with the D1S parametrization and the sdg interacting boson model (IBM). The quadrupole-hexadecapole constrained self-consistent mean-field potential energy surface is mapped onto the expectation value of the sdg-boson Hamiltonian. This procedure determines the parameters of the sdg-IBM Hamiltonian microscopically. Calculated excitation energies and transition strengths are compared to the ones obtained with a simpler sd-IBM, as well as with the experimental data. The Gogny-EDF mapped sdg-IBM reproduces spectroscopic properties of the studied nuclei as reasonably as in the case of the previous sdg-boson mapping calculations that were based on the relativistic EDF, indicating that the axial quadrupole-hexadecapole method is sound regardless of whether relativistic or nonrelativistic EDF is employed. The mapped sdg-IBM improves some of the results in lighter Sm and Gd isotopes compared to the mapped sd-IBM, implying the existence of significant hexadecapole correlations in those nuclei. For those nuclei with N ≥ 94, hexadecapole effects are minor, and the only significant difference between the two boson models can be found in the description of E0 monopole transitions.
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