Due to scheduling conflict (SBU's Chirality workshop), the talk will be rescheduled.
The search for gluon saturation is one of the major goals of the future Electron-Ion Collider (EIC). Significant progress has been made in advancing saturation physics to a precision science as we prepare for the EIC era. We contribute to these efforts by performing the first complete next-to-leading order (NLO) computation of inclusive dijet production in deeply inelastic electron-nucleus scattering at small-x within the Color Glass Condensate (CGC).
In this talk, I will introduce the basic elements of this computation by briefly reviewing the leading order result. Next, I will detail the main steps for calculating one-loop contributions. I will demonstrate the cancellation of all UV and IR divergences. Then, I will show that the rapidity singularity in the phase space of the emitted gluon can be absorbed into the JIMWLK evolution. We thus isolate the so-called impact factor, a necessary result to obtain reliable theoretical predictions for the EIC. I will conclude by outlining the future directions of our work.
This talk will be based on work in collaboration with Paul Caucal and Raju Venugopalan, arXiv:2108.06347 [hep-ph].
https://bnl.zoomgov.com/j/1601581422?pwd=dkdxVFgyRTZESUxIbUZDN1RmRURPQT09