Interplay of quadrupole and octupole degrees of freedom in the Gd isotopes

Abstract

A systematic theoretical investigation of the quadrupole and octupole collective properties across the Gd isotopic chain is performed employing a quadrupole-octupole axially symmetric model. These nuclei have recently attracted significant attention following the revelation that the maximum octupole collectivity in this region is located at 150Gd. The model parameters are optimized by fitting to the low-lying positive and negative-parity energy levels, as well as to known E0, E1, E2, and E3 transition strengths. Our primary objective is a simultaneous and unified description of quadrupole and octupole collectivity across the even-even Gd nuclei in the 84≤slant N ≤slant96 range, a region that includes the transition from spherical to rotational nuclear shapes. The results show a smooth evolution of the quadrupole deformation, highlighted by a distinct jump at the well-known N=90 critical point. The enhancement of quadrupole deformation is also correlated with the loss of non-zero octupole deformation, which is reported only for the lightest 148,150Gd nuclei. This translates into a fair agreement with the measured E3 strength, predicting a maximum B(E3) value for the 152Gd isotope.