Bottom and Charm Quark Mass Determination from Quarkonium at N3LO

Abstract

The non-perturbative nature of QCD at hadronic scales implied the development of phenomenological approaches such as quark models or, more recently, computer-based calculations using Lattice QCD. However, the unique properties of heavy quarkonium systems allow an entire calculation in terms of non-relativistic perturbative QCD. In this work, the bottomonium spectrum, up to n = 3, and the ground state charmonium states, are analyzed in the framework of Non-Relativistic Quantum Chromodynamics at N3LO. For bottomonium, finite charm quark mass effects in the QCD potential and the MS-pole mass relation are incorporated to the highest known order, O(3) in the -scheme counting. The bottom quark pole mass is expressed in terms of the MSR mass, a low-scale short-distance mass which cancels the u = 1/2 renormalon of the static potential. We study the n = 3 and n = 4 schemes, finding a negligible difference between the two if finite mc effects are smoothly incorporated in the MSR mass definition. We find that bottomonium n=3 states are not well behaved within perturbative NRQCD. Hence, fitting to the n=1,2 b b states we obtain mb(mb) = 4.216 0.039 GeV. Similarly, from the lowest lying charmonium states we find mc(mc)=1.273 0.054 GeV.