Inverse-scattering separable NN potential constrained to phase-shift data up to 2.5 GeV. I.- Uncoupled states

TL;DR

This paper presents a novel inverse-scattering method to construct energy-independent, complex separable potentials that accurately reproduce nucleon-nucleon phase shifts and absorption up to 2.5 GeV, using a multi-rank approach based on the $K$ matrix zeros.

Contribution

The paper introduces a new inverse-scattering technique for creating multi-rank, energy-independent separable potentials that fit phase-shift data and absorption, including complex form factors for non-Hermitian potentials.

Findings

Successfully reproduces phase-shift data up to 2.5 GeV.

Constructs channel-dependent, non-Hermitian potentials with minimal relativity.

Provides a framework extendable to spin-coupled states and relativistic kernels.

Abstract

We introduce a new method to construct, within inverse-scattering theory, an energy-independent separable potential capable of reproducing exactly both phase shift and absorption over a predefined energy range. The approach relies on the construction of non-overlapping multi-rank separable potentials, whose form factors are obtained by solving linear equations on intervals where the $K$ matrix does have zeros. Applications are made to nucleon-nucleon $NN$ interactions constrained to the SAID-SP07 phase-shift analysis up to 2.5 GeV lab energy. The inversion potentials are channel dependent with rank dictated by the number of zeros of the $K$ matrix, reproducing the data up to a selected upper momentum. The account for absorption yields complex separable form factors, resulting in a non-Hermitian potential. Applications are restricted to $NN$ spin-uncoupled states considering a Schr\"odinger-like wave equation with minimal relativity. Its extension to spin-coupled states and relativistic kernels are discussed.