Impact of ground-state correlations on the multipole response of nuclei: Ab initio calculations of moment operators

TL;DR

This paper introduces an ab initio framework using IMSRG to calculate nuclear response properties, demonstrating the importance of ground-state correlations and improving agreement with experimental data for certain nuclei.

Contribution

The paper develops a first-principles method to compute nuclear response moments, incorporating ground-state correlations with IMSRG, and benchmarks it against experimental data.

Findings

Ground-state correlations significantly affect multipole response.

IMSRG results better reproduce experimental data for $^{16}$O and $^{40}$Ca.

The moment method serves as a useful benchmark for other ab initio approaches.

Abstract

We develop a framework that allows to calculate integrated properties of the nuclear response from first principles. Using the ab initio in-medium similarity renormalization group (IMSRG), we calculate the expectation values of moment operators that are linked to the multipole response of nuclei. This approach is applied to the isoscalar mono- and quadrupole as well as the isovector dipole response of closed-shell nuclei from $^4$He to $^{78}$Ni for different chiral two- and three-nucleon interactions. We find that the inclusion of many-body correlations in the nuclear ground state significantly impacts the multipole response when going from the random-phase approximation to the IMSRG level. Our IMSRG calculations lead to an improved description of experimental data in $^{16}$O and $^{40}$Ca, including a good reproduction of the Thomas-Reiche-Kuhn enhancement factor. These findings highlight the utility of the moment method as a benchmark for other ab initio approaches that describe nuclear response functions through the explicit treatment of excited states.