Precise determination of the top-quark on-shell mass Mt via its scale-invariant perturbative relation to the top-quark MS mass mt( mt)

Abstract

It has been shown that the principle of maximum conformality (PMC) provides a systematic way to solve conventional renormalization scheme and scale ambiguities. The scale-fixed predictions for physical observables using the PMC are independent of the choice of renormalization scheme -- a key requirement of renormalization group invariance. In the paper, we derive new degeneracy relations based on the renormalization group equations that involve both the usual β-function and the quark mass anomalous dimension γm-function, respectively. These new degeneracy relations lead to an improved PMC scale-setting procedures, such that the correct magnitudes of the strong coupling constant and the MS-running quark mass can be fixed simultaneously. By using the improved PMC scale-setting procedures, the renormalization scale dependence of the MS-on-shell quark mass relation can be eliminated systematically. Consequently, the top-quark on-shell (or MS) mass can be determined without conventional renormalization scale ambiguity. Taking the top-quark MS mass mt( mt)=162.5+2.1-1.5 GeV as the input, we obtain Mt 172.41+2.21-1.57 GeV. Here the uncertainties are combined errors with those also from αs(MZ) and the approximate uncertainty stemming from the uncalculated five-loop terms predicted through the Pad\'e approximation approach.