Multiplicity-dependent forward jet production in proton-nucleus collisions

Abstract

Forward jet production in proton--nucleus collisions probes a dilute projectile scattering from a dense small-x nuclear gluon field, while the charged-particle multiplicity inside the jet probes the final-state cascade in the jet cone. We develop a factorization framework for single-inclusive forward jets with an internal multiplicity measurement by combining the Color Glass Condensate (CGC) description of the production process with soft-collinear effective theory (SCET) semi-inclusive jet functions. The construction preserves the inclusive limit exactly: at zero multiplicity weight it reduces to the known inclusive next-to-leading order (NLO)/resummed CGC forward-jet cross section. We define the multiplicity-measured jet operator in a CGC background, formulate the matching that separates PDF, BK/JIMWLK, Sudakov, SiJF, and multiplicity-evolution radiation, and identify the Wilson-line resolution mechanism through which saturation can modify the internal multiplicity evolution. The resulting framework shows that high-multiplicity forward jets are sensitive both to the quark/gluon mixture generated by the CGC production kernel and to finite-Qs corrections when an early in-cone splitting is resolved by the target. A baseline numerical implementation validates the factorized structure and illustrates the resulting multiplicity-conditioned nuclear modification.