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@ARTICLE{Blondel:415414,
      author       = {Blondel, A. and Gluza, J. and Jadach, S. and Janot, P. and
                      Riemann, T. and Akhundov, A. and Arbuzov, A. and Boels, R.
                      and Bondarenko, S. and Borowka, S. and Carloni Calame, C. M.
                      and Dubovyk, I. and Dydyshka, Ya. and Flieger, W. and
                      Freitas, A. and Grzanka, K. and Hahn, T. and Huber, T. and
                      Kalinovskaya, L. and Lee, R. and Marquard, P. and Montagna,
                      G. and Nicrosini, O. and Papadopoulos, C. G. and Piccinini,
                      F. and Pittau, R. and Pł aczek, W. and Prausa, M. and
                      Riemann, S. and Rodrigo, G. and Sadykov, R. and Skrzypek, M.
                      and Stöckinger, D. and Usovitsch, J. and Ward, B. F. L. and
                      Weinzierl, S. and Yang, G. and Yost, S. A.},
      title        = {{S}tandard {M}odel {T}heory for the {FCC}-ee: {T}he
                      {T}era-{Z}},
      reportid     = {PUBDB-2018-04490, arXiv:1809.01830. BU-HEPP-18-04.
                      CERN-TH-2018-145. IFJ-PAN-IV-2018-09. KW 18-003.
                      MITP/18-052. MPP-2018-143. SI-HEP-2018-21},
      year         = {2018},
      note         = {243 pages, Report on the 1st Mini workshop: Precision EW
                      and QCD calculations for the FCC studies: methods and tools,
                      12-13 January 2018, CERN, Geneva, Switzerland},
      abstract     = {The future 100-km circular collider FCC at CERN is planned
                      to operate in one of its modes as an electron-positron
                      FCC-ee machine. We give an overview of the theoretical
                      status compared to the experimental demands of one of four
                      foreseen FCC-ee operating stages, which is Z-boson resonance
                      energy physics, FCC-ee Tera-Z stage for short. The FCC-ee
                      Tera-Z will deliver the highest integrated luminosities as
                      well as very small systematic errors for a study the
                      Standard Model (SM) with unprecedented precision. In fact,
                      the FCC-ee Tera-Z will allow to study at least one more
                      quantum field theoretical perturbative order compared to the
                      LEP/SLC precision. The real problem is that the present
                      precision of theoretical calculations of the various
                      observables within the SM does not match that of the
                      anticipated experimental measurements. The bottle-neck
                      problems are specified. In particular, the issues of precise
                      QED unfolding and of the correct calculation of SM
                      pseudo-observables are critically reviewed. In an Executive
                      Summary we specify which basic theoretical calculations are
                      needed to meet the strong experimental expectations at the
                      FCC-ee Tera-Z. Several methods, techniques and tools needed
                      for higher order multi-loop calculations are presented. By
                      inspection of the Z-boson partial and total decay widths
                      analysis, arguments are given that at the beginning of
                      operation of the FCC-ee Tera-Z, the theory predictions may
                      be tuned to be precise enough not to limit the physics
                      interpretation of the measurements. This statement is based
                      on the anticipated progress in analytical and numerical
                      calculations of multi-loop and multi-scale Feynman integrals
                      and on the completion of two-loop electroweak radiative
                      corrections to the SM pseudo-observables this year. However,
                      the above statement is conditional as the theoretical issues
                      demand a very dedicated and focused investment by the
                      community.},
      keywords     = {quantum electrodynamics (INSPIRE) / electroweak
                      interaction: radiative correction (INSPIRE) / electroweak
                      interaction: precision measurement (INSPIRE) / form factor
                      (INSPIRE) / Yang-Mills (INSPIRE) / electron positron:
                      colliding beams (INSPIRE) / CERN Lab (INSPIRE) / FCC-ee
                      (INSPIRE) / SLAC SLC Linac (INSPIRE) / CERN LEP Stor
                      (INSPIRE) / programming (INSPIRE) / numerical calculations
                      (INSPIRE) / new physics (INSPIRE)},
      cin          = {ZEU-THEO},
      cid          = {I:(DE-H253)ZEU-THEO-20120731},
      pnm          = {611 - Fundamental Particles and Forces (POF3-611)},
      pid          = {G:(DE-HGF)POF3-611},
      experiment   = {EXP:(DE-MLZ)NOSPEC-20140101},
      typ          = {PUB:(DE-HGF)25 / PUB:(DE-HGF)29},
      eprint       = {1809.01830},
      howpublished = {arXiv:1809.01830},
      archivePrefix = {arXiv},
      SLACcitation = {$\%\%CITATION$ = $arXiv:1809.01830;\%\%$},
      doi          = {10.3204/PUBDB-2018-04490},
      url          = {https://bib-pubdb1.desy.de/record/415414},
}