Phenomenology of leading nucleon production in $ep$ collisions at HERA in the framework of fracture functions

TL;DR

This paper analyzes leading nucleon production in electron-proton collisions at HERA using fracture functions within perturbative QCD, extracting nucleon fracture functions from DIS data to describe parton distributions and structure functions.

Contribution

It introduces a novel fracture functions framework to phenomenologically parametrize leading nucleon production, providing detailed parton distributions and uncertainty estimates.

Findings

Good agreement with experimental data across various kinematic ranges.

Extracted nucleon fracture functions enable detailed parton distribution modeling.

Uncertainty sets allow propagation of errors to other observables.

Abstract

In recent years, several experiments at the $e^-p$ collider HERA have collected high precision deep inelastic scattering (DIS) data on the spectrum of leading nucleon carrying a large fraction of the proton's energy. In this paper, we have analyzed recent experimental data on the production of forward proton and neutron in DIS at HERA in the framework of a perturbative QCD. We propose a technique based on the fractures functions framework, and extract the nucleon fracture functions (nucleon FFs) ${\cal M}_2^{(n/p)} (x, Q^2; x_L)$ from global QCD analysis of DIS data measured by ZEUS collaboration at HERA. We have shown that an approach based on the fracture functions formalism allows us phenomenologically parametrize the nucleon FFs. Considering both leading neutron as well as leading proton production data at HERA, we present the results for the separate parton distributions for all parton species, including valence quark densities, the anti-quark densities, the strange sea distribution, and the gluon distribution functions. We proposed several parameterizations for the nucleon FFs and open the possibility of these asymmetries. The obtained optimum set of nucleon FFs is accompanied by Hessian uncertainty sets which allow one to propagate uncertainties to other observables interest. The extracted results for the $t$-integrated leading neutron $F_2^{\rm LN(3)} (x, Q^2; x_L)$ and leading proton $F_2^{\rm LP(3)} (x, Q^2; x_L)$ structure functions are in good agreement with all data analyzed, for a wide range of fractional momentum variable $x$ as well as the longitudinal momentum fraction $x_L$.