High Energy Evolution of Dipole Gluon Distribution Beyond Eikonal Approximation
Abstract
At high energy, the dipole gluon distribution is described at eikonal order by the Wilson-line dipole correlator, whose high-energy evolution is governed by the Balitsky-Kovchegov equation. Going beyond the eikonal approximation, we identify the subeikonal operator representing the dipole gluon distribution, consisting of a Wilson line with a single insertion of the light-cone chromoelectric field, and derive its high-energy evolution equation in the large-Nc limit under the single-logarithmic approximation. The resulting nonlinear evolution is coupled to the Wilson-line dipole correlator and incorporates gluon saturation effects. In the dilute limit, the subeikonal distribution grows as a power-law of the energy with exponent αs Nc/2π, less than one fifth of the eikonal value, while in the saturation regime it obeys the same Levin--Tuchin law as the eikonal correlator. These results constitute the first closed nonlinear evolution equation for the dipole gluon distribution at subeikonal order, a step toward precision small-x phenomenology and toward connecting small-x physics with the moderate-x dynamics.
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