A new analytic approach to physical observables in QCD

TL;DR

This paper introduces an analytic, ghost-free model for the QCD running coupling that incorporates non-perturbative effects, links IR and UV regions, and aligns with phenomenological IR freezing, providing improved insights into QCD observables.

Contribution

It presents a novel analytic model for the QCD coupling that avoids unphysical singularities and incorporates non-perturbative effects, extending the understanding of QCD in both IR and UV regions.

Findings

The model excludes unphysical singularities in the coupling.

The coupling freezes to a finite value at Q^2=0, consistent with IR freezing.

Calculated gluon condensate agrees with phenomenological estimates.

Abstract

An analytic ghost-free model for the QCD running coupling $\alpha(Q^2)$ is proposed. It is constructed from a more general approach we developed particularly for investigating physical observables of the type $F(Q^2)$ in regions that are inaccessible to perturbative methods of quantum field theory. This approach directly links the infrared (IR) and the ultraviolet(UV) regions together under the causal analyticity requirement in the complex $Q^2-$plane. Due to the inclusion of crucial non-perturbative effects, the running coupling in our model not only excludes unphysical singularities but also freezes to a finite value at the IR limit $Q^2=0$. This makes it consistent with a popular phenomenological hypothesis, namely the IR freezing phenomenon. Applying this model to compute the Gluon condensate, we obtain a result that is in good agreement with the most recent phenomenological estimate. Having calculated the $\beta-$function corresponding to our QCD coupling constant, we find that it behaves qualitatively like its perturbative counterpart, when calculated beyond the leading order and with a number of quark flavours allowing for the occurrence of IR fixed points.