Bottom and Charm Mass determinations from global fits to QQ bound states at N3LO

Abstract

The bottomonium spectrum up to n = 3 is studied within Non-Relativistic Quantum Chromodynamics up to N3LO. We consider finite charm quark mass effects both in the QCD potential and the MS-pole mass relation up to third order in the -scheme counting. The u = 1/2 renormalon of the static potential is canceled by expressing the bottom quark pole mass in terms of the MSR mass. A careful investigation of scale variation reveals that, while n = 1, 2 states are well behaved within perturbation theory, n = 3 bound states are no longer reliable. We carry out our analysis in the n = 3 and n = 4 schemes and conclude that, as long as finite mc effects are smoothly incorporated in the MSR mass definition, the difference between the two schemes is rather small. Performing a fit to bb bound states we find mb(mb) = 4.216 0.039 GeV. We extend our analysis to the lowest lying charmonium states finding mc(mc)=1.273 0.054 GeV. Finally, we perform simultaneous fits for mb and αs finding αs(nf=5)(mZ)=0.1178 0.0051. Additionally, using a modified version of the MSR mass with lighter massive quarks we are able to predict the uncalculated O(αs4) virtual massive quark corrections to the relation between the MS and pole masses.