Deformation effects on the surface neutron densities of stable S and Ni isotopes probed by proton elastic scattering via isotopic analysis

TL;DR

This study investigates how nuclear deformation influences surface neutron densities in stable S and Ni isotopes by combining proton elastic scattering experiments with advanced nuclear structure and reaction calculations.

Contribution

It introduces a comprehensive isotopic analysis method integrating nuclear structure models and reaction calculations to elucidate deformation effects on surface densities.

Findings

Deformation significantly affects the isotopic systematics of surface densities.

Relativistic impulse approximation with RHB densities reproduces experimental cross sections.

Isotopic analysis effectively probes nuclear deformation and single-particle features.

Abstract

To extract structure information from proton elastic scattering off S isotopes at 320 MeV and Ni isotopes at $E_p=180$ MeV, this study proposes isotopic analyses combining nuclear structure and reaction calculations. The isotonic analysis was repeated on $^{48}$Ca and $^{50}$Ti. The structure calculations were performed by using the spherical and deformed Relativistic Hartree--Bogoliubov (RHB) calculations, and the spherical nonrelativistic Skyrme Hartree--Fock--Bogoliubov calculations. The $(p,p)$ reactions were calculated using the relativistic impulse approximation (RIA) assuming the theoretical densities of target nuclei. The RIA calculations using the target densities obtained by the RHB calculation, along with the density-dependent point-coupling interactions reasonably reproduced the $(p,p)$ cross sections in the studied mass number region. The nuclear structure and $(p,p)$ reactions were analyzed in detail; especially, the effects of deformation on the isotopic systematics of the surface densities and $(p,p)$ cross sections were clarified. The deformation effects were found to be essential to describe the isotopic systematics of the experimental $(p,p)$ cross sections. Overall, isotopic and isotonic analyses are useful for extracting the nuclear structure information such as nuclear deformations and single-particle features from proton scattering, enabling sensitive probing of surface densities.