Spin Dependence of Small-Angle Proton-Nucleus Scattering

TL;DR

This paper investigates the spin asymmetry in small-angle polarized proton-nucleus scattering, revealing the importance of Coulomb-nuclear interference and absorptive corrections for explaining recent experimental data.

Contribution

It introduces a new explanation for the $A_N(t)$ asymmetry by emphasizing the role of interference between ultra-peripheral and central collisions, addressing previous theoretical shortcomings.

Findings

Absorptive corrections are crucial for accurate $A_N(t)$ predictions.

Interference between ultra-peripheral and central collisions dominates the asymmetry.

The model successfully explains recent PHENIX experiment data.

Abstract

We study the single-spin asymmetry, $A_N(t)$, arising from Coulomb-nuclear interference (CNI) at small 4-momentum transfer squared, $-t=q^2$, aiming at explanation of the recent data from the PHENIX experiment at RHIC on polarized proton-nucleus scattering, exposing a nontrivial $t$-dependence of $A_N$. We found that the failure of previous theoretical attempts to explain these data, was due to lack of absorptive corrections in the Coulomb amplitude of $pA$ elastic scattering. Our prominent observation is that the main contribution to $A_N(t)$ comes from interference of the amplitudes of ultra-peripheral and central collisions.