Electroproduction of heavy quarkonia: significance of dipole orientation

TL;DR

This paper investigates how the orientation of dipoles affects the electroproduction of heavy quarkonia, revealing that incorporating realistic dipole impact parameter correlations improves agreement with experimental data.

Contribution

It introduces a realistic model for dipole orientation and impact parameter correlation, significantly impacting the predicted $q$-dependence of heavy quarkonium electroproduction.

Findings

Model aligns well with experimental data on $q$-dependent cross sections.

Dipole orientation correlations influence the ratio of $\psi^{\, extprime}(2S)$ to $J/\psi$ yields.

Realistic impact parameter modeling improves understanding of interaction dynamics.

Abstract

The differential cross section $d\sigma/dq^2$ of diffractive electroproduction of heavy quarkonia on protons is a sensitive study tool for the interaction dynamics within the dipole representation. Knowledge of the transverse momentum transfer $\vec q$ provides a unique opportunity to identify the reaction plane, due to a strong correlation between the directions of $\vec q$ and impact parameter $\vec b$. On top of that, the elastic dipole-proton amplitude is subject to a strong correlation between $\vec b$ and dipole orientation $\vec r$. Most of models for $b$-dependent dipole cross section either completely miss this information, or make unjustified assumptions. We perform calculations basing on a realistic model for $\vec r$-$\vec b$ correlation, which significantly affect the $q$-dependence of the cross section, in particular the ratio of $\psi^{\,\prime}(2S)$ to $J/\psi$ yields. We rely on realistic potential models for the heavy quarkonium wave function, and the Lorentz-boosted Schr\"odinger equation. Good agreement with data on $q$-dependent diffractive electroproduction of heavy quarkonia is achieved.