Probing the neutron-skin thickness through $J/\psi$ photoproduction in ultra-peripheral collisions

TL;DR

This paper demonstrates that $J/\psi$ photoproduction in ultra-peripheral collisions can be used to probe neutron-skin thickness, revealing its impact on cross sections and offering a new method for nuclear tomography.

Contribution

It introduces a novel approach using diffractive vector-meson photoproduction to constrain neutron-skin thickness and transverse gluon distribution at high-energy colliders.

Findings

Larger neutron skin smooths the color-density profile and suppresses the coherent cross section at large $|t|$.

Increased neutron skin enhances incoherent cross section via configurational fluctuations.

The ratio of incoherent to coherent cross sections is a sensitive observable with reduced uncertainties.

Abstract

We study the impact of neutron-skin thickness on $J/\psi$ photoproduction in ultra-peripheral $^{208}\mathrm{Pb}+{}^{208}\mathrm{Pb}$ collisions. Within the Color Glass Condensate framework, we calculate coherent and incoherent cross sections and examine their dependence on the momentum transfer $|t|$ for different neutron-skin thicknesses. We find a clear imprint of the neutron skin on the $|t|$ spectra: a larger neutron skin leads to a smoother and more extended color-density profile, suppressing the coherent cross section at large $|t|$ while enhancing the incoherent cross section through increased event-by-event configurational fluctuations in the nuclear periphery. We further show that the ratio of incoherent to coherent integrated cross sections provides a particularly sensitive and robust observable, with reduced theoretical uncertainties. These results establish diffractive vector-meson photoproduction in ultra-peripheral collisions as a powerful tomographic tool to constrain the neutron-skin thickness and the transverse gluon distribution at the LHC and future Electron-Ion Colliders.