Abstract
Empirical moments of inertia, J1, J2, J3, of atomic nuclei with E(4+1 )/E(2+1 ) > 2.7 are extracted from experimental 2+g,γ energies and electric quadrupole matrix elements, determined from multi- step Coulomb excitation data, and the results are compared to expectations based on rigid and irro- tational inertial flow. Only by having the signs of the E2 matrix elements, i.e., ⟨2+g ||Mˆ (E2)||2+g ⟩ and
⟨0+g ||Mˆ (E2)||2+g ⟩⟨2+g ||Mˆ (E2)||2+γ ⟩⟨2+γ ||Mˆ (E2)||0+g ⟩, can a unique solution to all three components of the inertia tensor of an asymmetric top be obtained. While the absolute moments of inertia fall between the rigid and irrotational values as expected, the relative moments of inertia appear to be qualitatively consistent with the β2 sin2(γ) dependence of the Bohr Hamiltonian which originates from a SO(5) in- variance. A better understanding of inertial flow is central to improving collective models, particularly hydrodynamic-based collective models. The results suggest that a better description of collective dynam- ics and inertial flow for atomic nuclei is needed. The inclusion of vorticity degrees of freedom may provide a path forward. This is the first report of empirical moments of inertia for all three axes and the results should challenge both collective and microscopic descriptions of inertial flow.
