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Λ_{bar{textrm{MS}}}^((n_f=2)) from a momentum space analysis of the quark-antiquark static potential

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arxiv 1407.7503 v2 pith:BHSDFTQK submitted 2014-07-28 hep-ph hep-lathep-th

Λ_{bar{textrm{MS}}}^((n_f=2)) from a momentum space analysis of the quark-antiquark static potential

classification hep-ph hep-lathep-th
keywords potentialspacelatticetextrmlambdamomentumstaticanalysis
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We determine $\Lambda_{\bar{\textrm{MS}}}^{(n_f=2)}$ by fitting perturbative expressions for the quark-antiquark static potential to lattice results for QCD with $n_f=2$ dynamical quark flavors. To this end we use the perturbative static potential at the presently best known accuracy, i.e. up to ${\cal O}(\alpha_s^4)$, in momentum space. The lattice potential is computed on a fine lattice with $a \approx 0.042 \, \textrm{fm}$ in position space. To allow for a comparison and matching of both results, the lattice potential is transformed into momentum space by means of a discrete Fourier transform. The value of $\Lambda_{\bar{\textrm{MS}}}^{(n_f=2)}$ is extracted in momentum space. All sources of statistical and systematic errors are discussed. The uncertainty in the value of $\Lambda_{\bar{\textrm{MS}}}^{(n_f=2)}$ is found to be smaller than that obtained in a recent position space analysis of the static potential based on the same lattice data.

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    1-loop lattice PT improvement of Wilson loops enhances precision in extracting α_s from the static energy using TUMQCD (2+1)-flavor lattice data.