Novel Heavy-Quark Physics Phenomena

TL;DR

This paper reviews the current understanding of heavy quark distributions in nucleons, emphasizing non-perturbative intrinsic charm contributions, and discusses recent experimental data and theoretical predictions related to heavy-quark phenomena at high energies.

Contribution

It introduces a new prediction for intrinsic charm asymmetry in the proton based on lattice QCD and Light-Front Holographic QCD, connecting non-perturbative physics with experimental observations.

Findings

Predicted a significant intrinsic charm asymmetry at high x.

Recent ATLAS data constrains intrinsic charm models.

Non-perturbative heavy-quark effects influence high-energy collider processes.

Abstract

We review the current understanding of heavy quark parton distributions in nucleons and their impact on deep inelastic scattering, collider physics, and other processes at high energies. The determination of the heavy-quark parton distribution functions is particularly significant for the analysis of hard processes at LHC energies, including the forward rapidity high $x_\mathrm{F}$ domain. The contribution of "intrinsic" heavy quarks, which are multiply connected to the valence quarks of nucleons, is reviewed within non-perturbative physics which provides new information on the fundamental structure of hadrons in QCD. A new prediction for the non-perturbative intrinsic charm-anticharm asymmetry of the proton eigenstate has recently been obtained from a QCD lattice gauge theory calculation of the proton's $G_\mathrm{E}^p(Q^2)$ form factor. This form factor only arises from non-valence quarks and anti-quarks if they have different contributions in the proton's eigenstate. This result, together with the exclusive and inclusive connection and analytic constraints on the form of hadronic structure functions from Light-Front Holographic QCD (LFHQCD) predicts a significant non-perturbative $c(x,Q) - \bar{c}(x,Q)$ asymmetry in the proton structure function at high $x$, consistent with the dynamics predicted by intrinsic charm models. Recent ATLAS data on the associated production of prompt photons and charm-quark jets in $pp$ collisions at $\sqrt{s} = 8$ TeV has provided new constraints on non-perturbative intrinsic charm and tests of the LGTH predictions. We also focus on other experimental observables which have high sensitivity to the intrinsic heavy contributions to PDFs.