20Ne + 76Ge elastic and inelastic scattering at 306 MeV

TL;DR

This study investigates the elastic and inelastic scattering of 20Ne on 76Ge at 306 MeV to better understand the reaction mechanisms relevant for double charge exchange studies related to neutrinoless double-beta decay.

Contribution

It provides a detailed analysis of optical potentials and channel couplings for the 20Ne + 76Ge system, highlighting the importance of coupled channels effects in modeling scattering data.

Findings

Optical models alone cannot fully describe scattering above the grazing angle.

Deformation corrections improve the fit to experimental data.

Coupled channels effects are essential for accurate large-angle scattering predictions.

Abstract

Background: Double charge exchange (DCE) nuclear reactions have recently attracted much interest as tools to provide experimentally driven information about nuclear matrix elements of interest in the context of neutrinoless double-beta decay. In this framework, a good description of the reaction mechanism and a complete knowledge of the initial and final-state interactions are mandatory. Presently, not enough is known about the details of the optical potentials and nuclear response to isospin operators for many of the projectile-target systems proposed for future DCE studies. Among these, the 20Ne + 76Ge DCE reaction is particularly relevant due to its connection with 76Ge double-beta decay. Purpose: We intend to characterize the initial-state interaction for the 20Ne + 76Ge reactions at 306 MeV bombarding energy and determine the optical potential and the role of the couplings between elastic channel and inelastic transitions to the first low-lying excited states. Methods: We determine the experimental elastic and inelastic scattering cross-section angular distributions, compare the theoretical predictions by adopting different models of optical potentials with the experimental data, and evaluate the coupling effect through the comparison of the distorted-wave Born approximation calculations with the coupled channels ones. Results: Optical models fail to describe the elastic angular distribution above the grazing angle (9.4{\deg}). A correction in the geometry to effectively account for deformation of the involved nuclear systems improves the agreement up to about 14{\deg}. Coupled channels effects are crucial to obtain good agreement at large angles in the elastic scattering cross section.