Top Quark Mass Calibration for Monte Carlo Event Generators -- An Update

Autor(en)
Bahman Dehnadi, André H. Hoang, Oliver L. Jin, Vicent Mateu
Abstrakt

We generalize and update our former top quark mass calibration framework for Monte Carlo (MC) event generators based on the e

+ e

hadron-level 2-jettiness τ

2 distribution in the resonance region for boosted tt¯ production, that was used to relate the Pythia 8.205 top mass parameter mtMC to the MSR mass mtMSR(R) and the pole mass mtpole . The current most precise direct top mass measurements specifically determine mtMC . The updated framework includes the addition of the shape variables sum of jet masses τ

s and modified jet mass τ

m, and the treatment of two more gap subtraction schemes to remove the O (Λ

QCD) renormalon related to large-angle soft radiation. These generalizations entail implementing a more versatile shape-function fit procedure and accounting for a certain type of (m

t/Q)

2 power corrections to achieve gap-scheme and observable independent results. The theoretical description employs boosted heavy-quark effective theory (bHQET) at next-to-next-to-logarithmic order (N

2LL), matched to soft-collinear effective theory (SCET) at N

2LL and full QCD at next-to-leading order (NLO), and includes the dominant top width effects. Furthermore, the software framework has been modernized to use standard file and event record formats. We update the top mass calibration results by applying the new framework to Pythia 8.305, Herwig 7.2 and Sherpa 2.2.11. Even though the hadron-level resonance positions produced by the three generators differ significantly for the same top mass parameter mtMC value, the calibration shows that these differences arise from the hadronization modeling. Indeed, we find that mtMC agrees with mtMSR (1 GeV) within 200 MeV for the three generators and differs from the pole mass by 350 to 600 MeV.

Organisation(en)
Teilchenphysik
Externe Organisation(en)
Universidad de Salamanca, Deutsches Elektronen-Synchrotron DESY
Journal
Journal of High Energy Physics
Band
2023
Anzahl der Seiten
71
ISSN
1029-8479
DOI
https://doi.org/10.1007/JHEP12(2023)065
Publikationsdatum
09-2023
Peer-reviewed
Ja
ÖFOS 2012
103012 Hochenergiephysik
Schlagwörter
ASJC Scopus Sachgebiete
Nuclear and High Energy Physics
Link zum Portal
https://ucrisportal.univie.ac.at/de/publications/5d8e5ea7-e390-4813-bd31-0e077d0586aa