New Determinations of the Charm and Bottom Quark Masses Using QCD Quarkonium Sum Rules

Abstract

We reanalyze the perturbative QCD (pQCD) corrections to quarkonium QCD sum rules and extract the heavy quark masses mq(mq) (q=c,b). At present, the pQCD corrections to the correlation functions of two heavy-quark pseudoscalar and vector currents at zero momentum transfer, denoted as Mn,qX, th (X = P, V), are calculated up to the O(αs3) order. These corrections exhibit significant renormalization scheme and scale dependence, which introduces large theoretical uncertainties and deteriorates the precision of heavy quark mass determinations. In this work, we eliminate the renormalization scheme and scale ambiguities in the perturbative part of Mn,qX, th by adopting the Principle of Maximum Conformality (PMC) within the characteristic operator (CO) approach. The CO approach, a novel extension of the standard PMC procedure, simultaneously determines the effective coupling αs(Q*) and the effective quark mass mq(Q*). It systematically absorbs the nonconformal \βi\-terms and \γi\-terms via the renormalization group equations, yielding a strictly scheme- and scale-independent conformal perturbative series. Based on the improved PMC conformal series, we further provide reliable estimates for the unknown N4LO contributions using the Pad\'e approximation method. The final predicted heavy quark masses in the MS scheme read: mc(mc)=1275.8 0.4~MeV, extracted from the second moment of the charmed pseudoscalar correlator M2,cP; and mb(mb) = 4177.0 7.2~MeV, extracted from the first moment of the bottom vector correlator M1,bV. Both results agree well with the PDG world averages with deviations smaller than 1σ.