Gluon splitting at small x: a unified derivation for the JIMWLK, DGLAP and CSS equations
Abstract
We revisit the calculation of the next-to-leading order (NLO) corrections to dijet production in electron-ion collisions at small x. We focus on the back-to-back configuration where the relative transverse momentum P of the measured jets is much larger than both their momentum imbalance K and the target saturation momentum Qs(x,A). In this regime, we present for the first time a complete calculation of the real NLO corrections at leading power in 1/P. Our result exhibits TMD factorisation, with the same hard factor as at tree-level and a NLO correction to the Weisz\"acker-Williams (WW) gluon transverse momentum dependent (TMD) distribution which involves four Wilson-line operators. By studying different kinematical regimes for K and for the radiated gluon, we recover all the quantum evolutions that were previously identified for this process at NLO: the B-JIMWLK high-energy evolution and the CSS evolution of the gluon WW TMD, and the DGLAP evolution of the gluon PDF. When both K and the transverse momentum transferred by the target are large compared to Qs, all the Wilson-line operators boil down to the unintegrated gluon distribution and our NLO result for the gluon TMD can be used to isolate the transverse-momentum dependent gluon splitting function.
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