Top mass: challenges in definition and determination

Europe/Rome
Aula Seminari (LNF, Alte Energie)

Aula Seminari

LNF, Alte Energie

Barbara Mele (ROMA1), Enrico Nardi (LNF), Gennaro Corcella (LNF), Giuseppe Degrassi (ROMA3), Roberto Bonciani (ROMA1), Vittorio Del Duca (LNF)
Description
Aim of the workshop:
The top-quark mass definition and determination is a major subject of debate in both theoretical and experimental communities. Different strategies to relate the measured and theoretical quantities have been envisaged. The aim of this  3-day meeting is to convene experts on this topic to stimulate an informal discussion on different aspects of the issue. We plan to have only three or four talks each day, and plenty of time to discuss  the connection between the experimentally reconstructed top mass relying on Monte Carlo generators and different theoretical mass definitions, including the most advanced strategies. Implications of the top-mass determination for physics beyond the standard model will be also covered. The general approach and format will be pedagogical, the audience ranging from top-quark physics experts to graduate students, and should favour extended discussion among participants.


Confirmed Speakers:
 

Spyridon Argyropoulos        (DESY, Hamburg)
Vincenzo Branchina
           (Catania U. & INFN)
Roberto Chierici                        (CNRS & IPNL, Lyon)
Marina Cobal                             (Udine U. & INFN)
Roberto Franceschini          (CERN, Geneva)
Andrè Hoang
                          (Vienna U.)
Sandra Leone                     (INFN Pisa)
Fabio Maltoni                    
(Louvain U.)
Sven-Olaf Moch                 (DESY, Hamburg)
Michael Scherer                 (Heidelberg U.)
Adrian Signer                     (PSI, Villigen)


 
Participants
  • Adrian Signer
  • Andre Hoang
  • Anurag Tripathi
  • Barbara Mele
  • Dario Perricone
  • Domizia Orestano
  • Enrico Nardi
  • Fabio Maltoni
  • Francesco Moriello
  • Francesco Tramontano
  • Frederic Derue
  • Gennaro Corcella
  • Giuseppe Bevilacqua
  • Giuseppe Degrassi
  • Giuseppe Salamanna
  • Kataev Andrei
  • marina cobal
  • Markus Seidel
  • Martin Krauss
  • mauro papinutto
  • Michael Bender
  • Michael Scherer
  • Michal Dubovsky
  • Oliver Majersky
  • Pier Paolo Giardino
  • Ramona Gröber
  • Roberto Bonciani
  • Roberto chierici
  • Roberto Franceschini
  • Sandra Leone
  • Sofiane Boucenna
  • Spyros Argyropoulos
  • Sven-Olaf Moch
  • Teresa Barillari
  • Tomas Dado
  • Vincenzo Branchina
    • 10:00 11:00
      What is mt ? 1h
      An introductory discussion of the main basic issues regarding determinations of the top quark mass is given. After a reminder of how to extract a fundamental parameter in a quantum field theory from observables, I will concentrate on two issues. First, which observables are particulary well suited for a determination of the top mass. Second, are some mass definitions better than others?
      Speaker: Adrian Signer (PSI, Villigen)
      Slides
    • 11:00 12:00
      The Top Mass: Interpretation and Theoretical Uncertainties 1h
      I will talk about ways to better understand the concepts behind the Monte Carlo (MC) top mass parameter and about theoretical thoughts of how it may be related to renormalized field theory mass definitions. The only possible way I can currently see to clarify the question in a more concrete way is by comparing hadron-level QCD calculations for observables which are highly top mass sensitive to corresponding hadron-level MC output. I might show first results for such an analysis based on event-shape distributions.
      Speaker: Andre Hoang (Vienna U.)
      Slides
    • 15:00 16:00
      Measuring the top-quark running mass 1h
      The top-quark mass is a fundamental parameter of the Standard Model. We will motivate, why precision determinations of the top-quark mass are important in the upcoming high-energy run of the LHC and discuss the prerequisites in theory for the extraction of a well-defined mass parameter in a given renormalization scheme. We show that the top-quark's running mass in the MSbar scheme can be extracted with good precision at next-to-next-to-leading order in QCD and discuss a number of suitable observables.
      Speaker: Sven-Olaf Moch (DESY)
      Slides
    • 10:00 11:00
      Effects of color reconnection on the top mass 1h
      Color reconnection constitutes one of the main limiting factors for the high-precision top-mass measurements at hadron colliders. This talk will describe what color reconnection is, how it is modeled in event generators and how it affects the reconstruction of top final states, with a particular emphasis on the top mass. A series of new color reconnection models implemented in Pythia 8 will be presented, focusing on their implications for the existing top mass measurements and demonstrating ways in which future measurements could be used to constrain them.
      Speaker: Spyridon Argyropoulos (DESY, Hamburg)
      Slides
    • 11:00 11:30
      Measurements of the top quark mass at the Tevatron 30m
      I will show a summary of the top quark mass measurements at the Tevatron. In particular, I will concentrate on the evolution of the "template" method from its first application to the most recent results in the dilepton, lepton plus jets and all hadronic top pair decay channels
      Speaker: Sandra Leone (INFN Pisa)
      Slides
    • 11:30 12:00
      Top mass reconstruction techniques in ATLAS 30m
      The top quark is a fundamental constituent of the Standard Model. Its properties are accurately predicted by the theory, except for its mass, which remains a fundamental parameter of the SM. Since the start of the Large Hadron Collider many million of top-antitop quark pairs are available for study. With such a statistics, the physics of the top quark has entered the precision era. The main techniques used by the ATLAS experiment to reconstruct the top mass are discussed.
      Speaker: Marina Cobal (Udine U. & INFN)
      Slides
    • 14:30 15:00
      Top mass at CMS and World Averages 30m
      A precise measurement of the top mass is one of the key aspects for testing the Standard Model. A short review of the experimental methodologies used at CMS will be given, including both direct and indirect reconstruction methods. Results will be presented and discussed, with emphasis to the systematic errors, now dominating the total uncertainty. The last part of the talk will be devoted to explain how the combination of the measurements, at the LHC and with the Tevatron experiments, is performed.
      Speaker: Roberto Chierici (CMS/IPNL Lyon)
      Slides
    • 15:00 16:00
      Top quark mass at the LHC: kinematics and beyond 1h
      I will review some recent strategies for the top quark mass measurement, stressing in particular the foundation of each method on features of the kinematics of top quark production and decay at the Large Hadron Collider. Some of the advantages and drawbacks are discussed; in particular, I will present issues connected with the present status of the event simulations and theoretical calculations needed to carry out these measurements.
      Speaker: Dr Roberto Franceschini (CERN)
      Slides
    • 10:00 11:00
      Stability condition of the EW vacuum and top mass measurements 1h
      According to the standard analysis, the stability condition of the EW vacuum mainly depends on the values of the Higgs and top masses, MH and Mt. For this reason, it has been believed and strongly stressed in the last years that a precision measurement of Mt will provide an answer to the crucial question of whether our universe is in a stable or metastable vacuum, or at the edge of stability. Needless to say, the top quark mass is one of the fundamental parameters of the Standard Model: the top cross sections, the size of quantum corrections to different processes, the value of the top Yukawa coupling, just to mention few examples, all crucially depend on Mt. Obviously, a precision measurement of Mt is of the greatest importance. However, it will not be able to tell us anything on the "fate of our universe" (contrary to what is often stated). The reason is that new physics interactions, even if they show up only at very high scales (Planck scale), can strongly affect the stability condition of the EW vacuum. In the past, it was argued that new physics at very high energies cannot have impact on the vacuum stability properties, and this led to the believe that a precision measurement of Mt could "solve" the crucial stability problem.
      Speaker: Vincenzo Branchina (Catania U. & INFN)
      Slides
    • 11:00 12:00
      The Higgs Mass, the Top Mass and the Scale of New Physics 1h
      In view of the measured Higgs mass of 125 GeV, the perturbative renormalization group evolution of the Standard Model suggests that our Higgs vacuum might not be stable. I will present recent work where we connected the usual perturbative approach and the functional renormalization group which allows for a straightforward inclusion of higher-dimensional operators in the presence of an ultraviolet cutoff. In the latter framework vacuum stability can be studied in the presence of higher-dimensional operators. Their presence can have a sizable influence on the maximum ultraviolet scale of the Standard Model and the existence of instabilities. Further, I explain how such operators can be generated in specific models. Finally, I discuss the role of the top Yukawa coupling within this scenario.
      Speaker: Michael Scherer (Inst. fur Theoretische Physik, Heidelberg)
      Slides
    • 15:00 16:00
      The search for new physics in top-quark interactions 1h
      I would like to discuss how we could systematically look for new physics in top quark interactions at the LHC by using an EFT approach.
      Speaker: Fabio Maltoni