Strong coupling effects in near-barrier heavy-ion elastic scattering

TL;DR

This paper investigates how strong coupling effects influence near-barrier heavy-ion elastic scattering, highlighting the role of projectile and target structure, and presents conditions and measurements to better understand these phenomena.

Contribution

It provides a comprehensive analysis of strong coupling effects in near-barrier elastic scattering, emphasizing the importance of charge combinations and proposing new experimental approaches.

Findings

Coupling to target excited states can damp expected scattering patterns.

11Li exhibits unique scattering behavior not reproducible by standard models.

8B shows normal Fresnel scattering despite low breakup threshold.

Abstract

Accurate elastic scattering angular distribution data measured at bombarding energies just above the Coulomb barrier have shapes that can markedly differ from or be the same as the expected classical Fresnel scattering pattern depending on the structure of the projectile, the target or both. Examples are given such as 18O + 184W and 16O + 148,152Sm where the expected rise above Rutherford scattering due to Coulomb-nuclear interference is damped by coupling to the target excited states, and the extreme case of 11Li scattering, where coupling to the 9Li + n + n continuum leads to an elastic scattering shape that cannot be reproduced by any standard optical model parameter set. The recent availability of high quality 6He, 11Li and 11Be data provides further examples of the influence that coupling effects can have on elastic scattering. Conditions for strong projectile-target coupling effects are presented with special emphasis on the importance of the beam-target charge combination being large enough to bring about the strong coupling effects. Several measurements are proposed that can lead to further understanding of strong coupling effects by both inelastic excitation and nucleon transfer on near-barrier elastic scattering. A final note on the anomalous nature of 8B elastic scattering is presented as it possesses a more or less normal Fresnel scattering shape whereas one would a priori not expect this due to the very low breakup threshold of 8B. The special nature of 11Li is presented as it is predicted that no matter how far above the Coulomb barrier the elastic scattering is measured, its shape will not appear as Fresnel like whereas the elastic scattering of all other loosely bound nuclei studied to date should eventually do so as the incident energy is increased, making both 8B and 11Li truly "exotic".