Quantifying uncertainties due to irreducible three-body forces in deuteron-nucleus reactions

Abstract

Background: Deuteron-induced nuclear reactions are an essential tool for probing the structure of nuclei as well as astrophysical information such as (n,γ) cross sections. The deuteron-nucleus system is typically described within a Faddeev three-body model consisting of a neutron (n), a proton (p), and the target nucleus (A) interacting through pairwise phenomenological potentials. While Faddeev techniques enable the exact description of the three-body dynamics, their predictive power is limited in part by the omission of irreducible neutron-proton-nucleus three-body force (n-p-A 3BF). Results: By comparing the Faddeev and NCSM/RGM results, we show that the irreducible n-p-α 3BF has a non-negligible effect on bound state and scattering observables alike. Specifically, the Faddeev approach %are yields a 6Li ground state that is approximately 600~keV shallower than the one obtained with the NCSM/RGM. Additionally, the Faddeev calculations for d+α scattering yield a 3+ resonance that is located approximately 400~keV higher in energy compared to the NCSM/RGM result. The shape of the d+α angular distributions computed using the two approaches also differ, owing to the discrepancy in the predictions of the 3+ resonance energy.