QCD Static Force in Gradient Flow

TL;DR

This paper calculates the QCD static force and potential using gradient flow at next-to-leading order, aiming to improve lattice QCD computations and understanding of QCD interactions at various distances.

Contribution

It provides the first next-to-leading order analysis of the static force with gradient flow, exploring properties at arbitrary flow times and in the zero flow time limit.

Findings

Gradient flow improves convergence of static force calculations.

The static force is free from the $O( ext{Lambda}_{ m QCD})$ renormalon.

Results are applicable for lattice QCD studies at different flow times.

Abstract

We compute the QCD static force and potential using gradient flow at next-to-leading order in the strong coupling. The static force is the spatial derivative of the static potential: it encodes the QCD interaction at both short and long distances. While on the one side the static force has the advantage of being free of the $O(\Lambda_{\rm QCD})$ renormalon affecting the static potential when computed in perturbation theory, on the other side its direct lattice QCD computation suffers from poor convergence. The convergence can be improved by using gradient flow, where the gauge fields in the operator definition of a given quantity are replaced by flowed fields at flow time $t$, which effectively smear the gauge fields over a distance of order $\sqrt{t}$, while they reduce to the QCD fields in the limit $t \to 0$. Based on our next-to-leading order calculation, we explore the properties of the static force for arbitrary values of $t$, as well as in the $t \to 0$ limit, which may be useful for lattice QCD studies.