Exact Neutron-Proton Wavefunctions Using the Phase Function Method

Abstract

Radial phase shifts (δ(r)), amplitude functions (A(r)), and exact wavefunctions (u(r)) for various uncoupled S, P, and D channels of neutron--proton scattering have been calculated using the Phase Function Method (PFM). In these calculations, inverse potentials obtained from the Morse function as the zeroth-order reference potential are employed. The parameters of the Morse potential were optimized using the comprehensive GRANADA partial wave analysis, consisting of 6713 experimental np phase shift data points from 1950 to 2013, by minimizing the mean square error (MSE) as a cost function. The present work provides detailed radial dependence of δ(r), A(r), and u(r) up to 5~fm for laboratory energies E lab = [1, 10, 50, 100, 150, 250, 350]~MeV. The obtained wavefunctions show excellent agreement with high-precision Nijmegen-II results, highlighting the accuracy and transparency of the PFM approach for uncoupled scattering states.