Application of the Principle of Maximum Conformality to the Top-Quark Charge Asymmetry at the LHC

Abstract

The Principle of Maximum Conformality (PMC) provides a systematic and process-independent method to derive renormalization scheme- and scale- independent fixed-order pQCD predictions. In Ref.pmc3, we studied the top-quark charge asymmetry at the Tevatron. By applying the PMC, we have shown that the large discrepancies for the top-quark charge asymmetry between the Standard Model estimate and the CDF and D0 data are greatly reduced. In the present paper, with the help of the Bernreuther-Si program, we present a detailed PMC analysis on the top-quark pair production up to next-to-next-to-leading order level at the LHC. After applying PMC scale setting, the pQCD prediction for the top-quark charge asymmetry at the LHC has very small scale uncertainty; e.g., A C| 7 TeV;PMC =(1.15+0.01-0.03)\%, A C| 8 TeV;PMC =(1.03+0.01+0.00)\%, and A C| 14 TeV;PMC =(0.62+0.00-0.02)\%. The corresponding predictions using conventional scale setting are: A C| 7 TeV;Conv. =(1.23+0.14-0.14)\%, A C| 8 TeV;Conv. =(1.11+0.17-0.13)\%, and A C| 14 TeV;Conv. =(0.67+0.05-0.05)\%. In these predictions, the scale errors are predicted by varying the initial renormalization and factorization scales in the ranges μ initr∈[mt/2,2mt] and μf∈[mt/2,2mt]. The PMC predictions are also in better agreement with the available ATLAS and CMS data. In addition, we have calculated the top-quark charge asymmetry assuming several typical cuts on the top-pair invariant mass Mtt. For example, assuming Mtt>0.5 ~ TeV and μf=μ initr =mt, we obtain A C| 7 TeV;PMC=2.67\%, A C| 8 TeV;PMC=2.39\%, and A C| 14 TeV;PMC=1.28\%.