A Precise αs Determination from the R-improved QCD Static Energy

Abstract

The strong coupling αs is extracted with high precision through fits to lattice-QCD data for the static energy. Our theoretical framework is based on R-improving the three-loop fixed-order prediction for the static energy: we remove the u=1/2 renormalon and resum the associated large infrared logarithms. Combined with radius-dependent renormalization scales (the so-called profile functions), this procedure extends the range of validity of perturbation theory to distances as large as 0.5\,fm. In addition, we resum large ultrasoft logarithms to N3LL accuracy using renormalization-group evolution. Since the standard four-loop R-evolution treats N4LL and higher-order contributions asymmetrically, we also incorporate this potential source of bias in our analysis. Our estimate of the perturbative uncertainty is obtained through a random scan over the parameters controlling the profile functions and the implementation of R-evolution. We analyze how the extracted value of αs depends on the shortest and longest distances included in the fit, on the details of the R-evolution procedure, on the fitting strategy itself, and on the accuracy of ultrasoft resummation. From our final analysis, and after evolution to the Z pole, we obtain α(nf=5)s(mZ)=0.1170 0.0009, a result fully compatible with the world average and with a comparable uncertainty.

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