Electromagnetic observables of open-shell nuclei from coupled-cluster theory
Francesca Bonaiti, Sonia Bacca, G. Hagen, G. R. Jansen
Abstract
We develop a new method to describe electromagnetic observables of open-shell nuclei with two nucleons outside a closed shell. This approach combines the equation-of-motion coupled-cluster method for such systems and the Lorentz integral transform technique, expanding the applicability of coupled-cluster theory for electromagnetic observables beyond closed-(sub)shell nuclei. To validate this new approach, we compute the non-energy-weighted dipole sum rule and the dipole polarizability of ${}^{16,24}\mathrm{O}$ in both the closed-(sub)shell and the new equation-of-motion coupled-cluster frameworks, finding agreement within error bars. We then analyze the evolution of the dipole polarizability along the oxygen and calcium isotopic chains. Our predictions agree well with available experimental data and other available theoretical calculations for the closed-(sub)shell ${}^{16,22}\mathrm{O}$ and the open-shell $^{18}\mathrm{O}$. In the calcium isotopes, we observe that our dipole polarizability predictions for open-shell nuclei are lower than those of closed-(sub)shell nuclei. We expect that our predictions for $^{24}\mathrm{O}$ and ${}^{54,56}\mathrm{Ca}$ will motivate future experimental studies at the drip line.