-deuteron low-energy s-wave phase shifts and momentum correlation functions in Faddeev formulation

Abstract

The low-energy -deuteron scattering is investigated through the solution of Faddeev equations, employing three sets of the currently available parametrization of the -nucleon interactions. One of these is the chiral NLO interaction parametrized by the J\"ulich group, and the other two are based on the calculations by the HAL-QCD method. The s-wave phase shifts in the J=3/2 and J=1/2 states are presented. Three-body wave functions in coordinate space are constructed from the Faddeev amplitudes in momentum space. These functions are used in the calculation of d momentum correlation functions. The effects of the deuteron breakup are significant in the J=3/2 channel. The differences in the magnitude of the calculated correlation function show the quantitative difference of the N interactions in the spin-isospin channels. The prospective experimental data on the d momentum correlation function could contribute to a better description of the N interactions.