Properties of a separable representation of optical potentials

TL;DR

This paper investigates the non-local properties and convergence of separable optical potentials in nuclear physics, revealing target-dependent non-locality at low energies and target-independent behavior at higher energies, with implications for microscopic models.

Contribution

It provides a detailed analysis of the non-locality and convergence of separable optical potentials, highlighting their energy dependence and relation to microscopic potentials.

Findings

Off-diagonal behavior deviates from Gaussian form but is accurate near maximum depth.

Non-locality is target-dependent at low energy ranges (0-50 MeV).

Including larger energy ranges results in target-independent non-locality.

Abstract

Background: Separable interactions have a long history in nuclear physics. In the last few years, separable expansions have been used to represent the optical potential between a nucleon (proton or neutron) and a target. Purpose: We explore the non-local properties of these separable optical potentials as well as their convergence behavior. Method: For a couple of cases, we use the generalized Ersnt-Shakin-Thaler scheme to generate separable interactions starting from local optical potentials. We study the variation of the interaction with energy range and rank. Results: We find that, overall the off-diagonal behavior of the converged separable interaction deviates from the Gaussian form assumed by Perey and Buck. However, in the region surrounding the maximum depth the Gaussian form works quite well. Focusing on this region, we study potentials describing neutron elastic scattering on $^{16}$O and $^{48}$Ca for beam energies in the range of $ E=$10-50 MeV and explore several measures of non-locality of the separable interactions. Conclusions: When the energy range considered for generating the separable interaction is $0\le E_{range}\le 50$ MeV, the resulting non-locality is large and target dependent. Contrarily, the nonlocality obtained including larger energy ranges in the separable procedure is independent of the target and other details of the original local potential. We find that, even when including in the expansion many support points with energy ranges $0\le E_{range}\le 2400$ MeV, the resulting potential retains non-local behavior. Connections with microscopic optical potentials as well as other transformations used in the nucleon-nucleon domain are made.