Monte Carlo Top Quark Mass Calibration

Abstract

The most precise top quark mass measurements use kinematic reconstruction methods, determining the top mass parameter of a Monte Carlo event generator, mt MC. Due to the complicated interplay of hadronization and parton shower dynamics in Monte Carlo event generators relevant for kinematic reconstruction, relating mt MC to field theory masses is a non-trivial task. In this talk we report on a calibration procedure to determine this relation using hadron level QCD predictions for 2-Jettiness in e+e- annihilation, an observable which has kinematic top mass sensitivity and a close relation to the invariant mass of the particles coming from the top decay. The theoretical ingredients of the QCD prediction are reviewed. Fitting e+e- 2-Jettiness calculations at NLL/NNLL order to PYTHIA 8.205, we find that mt MC agrees with the MSR mass mt,1\, GeV MSR within uncertainties. At NNLL we find mt MC = mt,1\, GeV MSR + (0.18 0.22)\, GeV. mt MC can differ from the pole mass mt pole by up to 600\, MeV, and using the pole mass generally leads to larger uncertainties. At NNLL we find mt MC = mt pole + (0.57 0.28)\, GeV as the fit result. In contrast, converting mt,1\, GeV MSR obtained at NNLL to the pole mass gives a result for mt pole that is substantially larger and incompatible with the fit result. We also explain some theoretical aspects relevant for employing the C-parameter as an alternative calibration observable.