Add to ORKGWe compare lattice data for the short-distance part of the static energy in 2+1 flavor quantum chromodynamics (QCD) with perturbative calculations, up to next-to-next-to-next-to leading-logarithmic accuracy. We show that perturbation theory describes very well the lattice data at short distances, and exploit this fact to obtain a determination of the product of the lattice scale r_0 with the QCD scale Lambda_{MS}. With the input of the value of r_0, this provides a determination of the strong coupling alpha_s at the typical distance scale of the lattice data. We obtain alpha_s(1.5 GeV)=0.326\pm0.019, which provides a novel determination of alpha_s at low energy and with three-loop accuracy (including resummation of the leading ultrasoft log...
We compute the static energy of QCD at short distances at next-to-next-to-next-to-leading logarithmi...
Precision tests of QCD perturbation theory are not readily available from experimental data. The mai...
We use the recently obtained theoretical expression for the complete QCD static energy at next-to-ne...
We compare lattice data for the short-distance part of the static energy in 21 flavor quantum chromo...
We compare lattice data for the short-distance part of the static energy in 2+1 flavor quantum chrom...
Comparing perturbative calculations with a lattice computation of the static energy in quantum chrom...
We present an update of our determination of the strong coupling α s from the quantum chromodynamics...
The determination of αs(MZ) via perturbative analyses of short-distance-sensitive lattice observable...
We review the determination of the strong coupling αs from the comparison of the perturbative expres...
We obtain a determination of the strong coupling as in quantum chromodynamics, by comparing perturba...
Abstract We determine the strong coupling constant α s from the static QCD potential by matching a t...
We present two determinations of the strong coupling α s . The first one is from the static energy a...
We review one of the most accurate low-energy determinations of αs. Comparing at short distances the...
We review one of the most accurate low-energy determinations of αs. Comparing at short distances the...
We determine the strong coupling constant αs(MZ) from the static QCD potential by matching a lattice...
We compute the static energy of QCD at short distances at next-to-next-to-next-to-leading logarithmi...
Precision tests of QCD perturbation theory are not readily available from experimental data. The mai...
We use the recently obtained theoretical expression for the complete QCD static energy at next-to-ne...
We compare lattice data for the short-distance part of the static energy in 21 flavor quantum chromo...
We compare lattice data for the short-distance part of the static energy in 2+1 flavor quantum chrom...
Comparing perturbative calculations with a lattice computation of the static energy in quantum chrom...
We present an update of our determination of the strong coupling α s from the quantum chromodynamics...
The determination of αs(MZ) via perturbative analyses of short-distance-sensitive lattice observable...
We review the determination of the strong coupling αs from the comparison of the perturbative expres...
We obtain a determination of the strong coupling as in quantum chromodynamics, by comparing perturba...
Abstract We determine the strong coupling constant α s from the static QCD potential by matching a t...
We present two determinations of the strong coupling α s . The first one is from the static energy a...
We review one of the most accurate low-energy determinations of αs. Comparing at short distances the...
We review one of the most accurate low-energy determinations of αs. Comparing at short distances the...
We determine the strong coupling constant αs(MZ) from the static QCD potential by matching a lattice...
We compute the static energy of QCD at short distances at next-to-next-to-next-to-leading logarithmi...
Precision tests of QCD perturbation theory are not readily available from experimental data. The mai...
We use the recently obtained theoretical expression for the complete QCD static energy at next-to-ne...