The importance of kinematic twists and genuine saturation effects in dijet production at the Electron-Ion Collider

TL;DR

This paper analyzes the impact of kinematic twists and genuine saturation effects on dijet production at the Electron-Ion Collider, comparing advanced theoretical frameworks to identify observable saturation phenomena.

Contribution

It extends previous analyses by including the improved TMD framework and isolates genuine saturation effects in dijet production, providing numerical estimates for future experiments.

Findings

Genuine saturation effects are distinguishable from kinematic corrections.

The CGC framework captures higher saturation contributions beyond TMD.

Certain kinematic windows enhance the visibility of saturation effects.

Abstract

We compute the differential yield for quark anti-quark dijet production in high-energy electron-proton and electron-nucleus collisions at small $x$ as a function of the relative momentum $\boldsymbol{P}_\perp$ and momentum imbalance $\boldsymbol{k}_\perp$ of the dijet system for different photon virtualities $Q^2$, and study the elliptic and quadrangular anisotropies in the relative angle between $\boldsymbol{P}_\perp$ and $\boldsymbol{k}_\perp$. We review and extend the analysis in [1], which compared the results of the Color Glass Condensate (CGC) with those obtained using the transverse momentum dependent (TMD) framework. In particular, we include in our comparison the improved TMD (ITMD) framework, which resums kinematic power corrections of the ratio $k_\perp$ over the hard scale $Q_\perp$. By comparing ITMD and CGC results we are able to isolate genuine higher saturation contributions in the ratio $Q_s/Q_\perp$ which are resummed only in the CGC. These saturation contributions are in addition to those in the Weizs\"ackerWilliams gluon TMD that appear in powers of $Q_s/k_\perp$. We provide numerical estimates of these contributions for inclusive dijet production at the future Electron-Ion Collider, and identify kinematic windows where they can become relevant in the measurement of dijet and dihadron azimuthal correlations. We argue that such measurements will allow the detailed experimental study of both kinematic power corrections and genuine gluon saturation effects.