Static energy in (2+1+1)-flavor lattice QCD: Scale setting and charm effects

We present results for the static energy in (2 + 1 + 1)-flavor QCD over a wide range of lattice spacings and several quark masses, including the physical quark mass, with ensembles of lattice-gauge-field configurations made available by the MILC Collaboration. We obtain results for the static energy out to distances of nearly 1 fm, allowing us to perform a simultaneous determination of the scales r1 and r0, as well as the string tension sigma. For the smallest three lattice spacings we also determine the scale r2. Our results for r0/r1 and r0pagree with published (2 + 1)-flavor results. However, our result for r1/r2 differs significantly from the ffiffi sigma value obtained in the (2 + 1)-flavor case, which is most likely due to the effect of the charm quark. We also report results for r0, r1, and r2 in fm, with the former two being slightly lower than published (2 + 1)-flavor results. We study in detail the effect of the charm quark on the static energy by comparing our results on the finest two lattices with the previously published (2 + 1)-flavor QCD results at similar lattice spacing. We find that for r > 0.2 fm our results on the static energy agree with the (2 + 1)-flavor result, implying the decoupling of the charm quark for these distances. For smaller distances, on the other hand, we find that the effect of the dynamical charm quark is noticeable. The lattice results agree well with the two-loop perturbative expression of the static energy incorporating finite charm mass effects. This is the first time that the decoupling of the charm quark is observed and quantitatively analyzed on lattice data of the static energy.

Automated summary

We present results for the static energy in (2 + 1 + 1)-flavor QCD over a wide range of lattice spacings and several quark masses, including the physical quark mass, with ensembles of lattice-gauge-field configurations made available by the MILC Collaboration. We obtain results for the static energy out to distances of nearly 1 fm, allowing us to perform a simultaneous determination of the scales r1 and r0, as well as the string tension sigma. Our findings indicate the decoupling of the charm quark for distances above 0.2 fm, while its effect is noticeable for smaller distances.