Gluon distributions and their applications to Ioffe-time distributions

TL;DR

This paper models gluon distributions in the nucleon using QCD-guided parametrizations, fits them to data, and explores their applications to Ioffe-time distributions to aid lattice QCD calculations and understand gluon structure.

Contribution

It introduces a QCD-guided parametrization of gluon distributions in the helicity basis and applies it to Ioffe-time distributions, aiding lattice QCD data analysis.

Findings

The polarized gluon distribution agrees with global analysis.

The model supports the $(1-x)$ suppression in helicity distributions.

Calculated Ioffe-time distributions assist in lattice QCD extrapolations.

Abstract

We investigate unpolarized and polarized gluon distributions and their applications to the Ioffe-time distributions, which are related to lattice QCD calculations of parton distribution functions. Guided by the counting rules based on the perturbative QCD at large momentum fraction $x$ and the color coherence of gluon couplings at small $x$, we parametrize gluon distributions in the helicity basis. By fitting the unpolarized gluon distribution, the inferred polarized gluon distribution from our parametrization agrees with the one from global analysis. A simultaneous fit to both unpolarized and polarized gluon distributions is also performed to explore the model uncertainty. The agreement with the global analysis supports the $(1-x)$ power suppression of the helicity-antialigned distribution relative to the helicity-aligned distribution. The corresponding Ioffe-time distributions and their asymptotic expansions are calculated from the gluon distributions. Our results of the Ioffe-time distributions can provide guidance to the extrapolation of lattice QCD data to the region lacking precise gluonic matrix elements. Therefore, they can help regulate the ill-posed inverse problem associated with extracting the gluon distributions from discrete data from first-principle calculations, which are available in a limited range of the nucleon momentum and the spatial separation between the gluonic currents. Given various limitations in obtaining lattice QCD data at large Ioffe time, phenomenological approaches can provide important complementary information to extract the gluon distributions in the entire $x$ region. The possibility of investigating higher-twist effects and other systematic uncertainties in the contemporary first-principle calculations of parton distributions from phenomenologically well-determined Ioffe-time distributions in the large Ioffe-time region is also discussed.