Vector quarkonia at the LHC with JETHAD: A high-energy viewpoint

TL;DR

This review explores vector quarkonium production at the LHC using advanced QCD techniques, highlighting the potential for precision high-energy QCD studies and insights into quarkonium production mechanisms.

Contribution

It applies the ZCW19+ determination and hybrid high-energy collinear factorization with BFKL resummation to analyze vector quarkonium production, extending previous models.

Findings

High-energy series stability improves with forward particle tagging.

Vector quarkonia production can be used for precision QCD studies.

Results support the hybrid factorization approach for quarkonium analysis.

Abstract

In this review we discuss and extend the study of the inclusive production of vector quarkonia, $J/\psi$ and $\Upsilon$, emitted with large transverse momenta and rapidities at the LHC. We adopt the novel ZCW19$^+$ determination to depict the quarkonium production mechanism at the next-to-leading level of perturbative QCD. This approach is based on the nonrelativistic QCD formalism well adapted to describe the production of a quarkonium state from the collinear fragmentation of a gluon or a constituent heavy quark at the lowest energy scale. We rely upon the NLL/NLO$^+$ hybrid high-energy and collinear factorization for differential cross sections, where the standard collinear formalism is enhanced by the BFKL resummation of next-to-leading energy logarithms arising in the $t$-channel. We employ the JETHAD method to analyze the behavior of rapidity distributions for double inclusive vector-quarkonium and inclusive vector-quarkonium plus jet emissions. We discovered that the natural stability of the high-energy series, previously observed in observables sensitive to the emission of hadrons with heavy flavor detected in the rapidity acceptance of LHC barrel calorimeters, becomes even more manifest when these particles are tagged in forward regions covered by endcaps. Our findings brace the important message that vector quarkonia at the LHC via the hybrid factorization offer a unique chance to perform precision studies of high-energy QCD, as well as an intriguing opportunity to shed light on the quarkonium production puzzle.