Application of the Principle of Maximum Conformality to Top-Pair Production

Abstract

A major contribution to the uncertainty of finite-order perturbative QCD predictions is the perceived ambiguity in setting the renormalization scale μr. For example, by using the conventional way of setting μr ∈ [mt/2,2mt], one obtains the total t t production cross-section σt t with the uncertainty σt t/σt t (+3%-4%) at the Tevatron and LHC even for the present NNLO level. The Principle of Maximum Conformality (PMC) eliminates the renormalization scale ambiguity in precision tests of Abelian QED and non-Abelian QCD theories. In this paper we apply PMC scale-setting to predict the t t cross-section σtt at the Tevatron and LHC colliders. It is found that σtt remains almost unchanged by varying μ initr within the region of [mt/4,4mt]. The convergence of the expansion series is greatly improved. For the (qq)-channel, which is dominant at the Tevatron, its NLO PMC scale is much smaller than the top-quark mass in the small x-region, and thus its NLO cross-section is increased by about a factor of two. In the case of the (gg)-channel, which is dominant at the LHC, its NLO PMC scale slightly increases with the subprocess collision energy s, but it is still smaller than mt for s 1 TeV, and the resulting NLO cross-section is increased by 20%. As a result, a larger σtt is obtained in comparison to the conventional scale-setting method, which agrees well with the present Tevatron and LHC data. More explicitly, by setting mt=172.9 1.1 GeV, we predict σ Tevatron,\;1.96\,TeV = 7.626+0.265-0.257 pb, σ LHC,\;7\,TeV = 171.8+5.8-5.6 pb and σ LHC,\;14\,TeV = 941.3+28.4-26.5 pb. [full abstract can be found in the paper.]