Efficacy of the symmetry-adapted basis for ab initio nucleon-nucleus interactions for light- and intermediate-mass nuclei

We study the efficacy of a new ab initio framework that combines the symmetry-adapted (SA) nocore shell-model approach with the resonating group method (RGM) for unified descriptions of nuclear structure and reactions. We obtain ab initio neutron-nucleus interactions for 4He, 16O, and 20Ne targets, starting with realistic nucleon-nucleon potentials. We discuss the effect of increasing model space sizes and symmetry-based selections on the SA-RGM norm and direct potential kernels, as well as on phase shifts, which are the input to calculations of cross sections. We demonstrate the efficacy of the SA basis and its scalability with particle numbers and model space dimensions, with a view toward ab initio descriptions of nucleon scattering and capture reactions up through the medium-mass region. (c) 2022 Elsevier B.V. All rights reserved.

Automated summary

We study the effectiveness of a new ab initio framework that combines the symmetry-adapted nocore shell-model approach with the resonating group method for unified descriptions of nuclear structure and reactions. Ab initio neutron-nucleus interactions are obtained for 4He, 16O, and 20Ne targets. The study demonstrates the efficacy of the proposed framework and its scalability with particle numbers and model space dimensions, with the aim of ab initio descriptions of nucleon scattering and capture reactions in the medium-mass region.