Fedynitch,Anatoli / Assistant Research Fellow

Research Interest

• Multimessenger Astrophysics
• High-Energy and Ultra-High Energy Cosmic Rays
• Modeling of hadronic and nuclear interactions
• Neutrinos

Experience

• 09/2021 – 10/2021: Consultant, Institute of Physics, Academia Sinica, Taiwan
• 09/2019 – 08/2021: JSPS International Fellow, Institute for Cosmic Ray Research (ICRR), The University of Tokyo, Japan
• 01/2019 – 08/2019: Postdoc in Theoretical and Experimental Astroparticle Physics, University of Alberta, Canada
• 01/2016 – 12/2018: Postdoc in Theoretical Astroparticle Physics, DESY Zeuthen, Germany

Publication

Journal Papers

• [1]     Fedynitch A., Huber M., accepted, “Data-driven hadronic interaction model for atmospheric lepton flux calculations”, PHYSICAL REVIEW D. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [2]     Abbasi R. et al., 2022, “Improved Characterization of the Astrophysical Muon–neutrino Flux with 9.5 Years of IceCube Data”, The Astrophysical Journal, 928(1), 50. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [3]     Fedynitch A., Woodley W., Piro M.-C., 2022, “On the Accuracy of Underground Muon Intensity Calculations”, The Astrophysical Journal, 928(1), 27. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [4]     Albrecht Johannes, Cazon Lorenzo, Dembinski Hans, Fedynitch Anatoli, Kampert Karl-Heinz, Pierog Tanguy, Rhode Wolfgang, Soldin Dennis, Spaan Bernhard, Ulrich Ralf, Unger Michael, 2022, “The Muon Puzzle in cosmic-ray induced air showers and its connection to the Large Hadron Collider”, Astrophysics and Space Science, 367(3), 27. (SCIE) (IF: 1.83; SCI ranking: 63.2%)
  
  
• [5]     Aartsen M. G. et al., 2021, “Detection of a particle shower at the Glashow resonance with IceCube”, Nature, 591(7849), 220-224. (SCIE) (IF: 49.962; SCI ranking: 1.4%)
  
  
• [6]     Globus Noémie, Fedynitch Anatoli, Blandford Roger D., 2021, “Polarized Radiation and the Emergence of Biological Homochirality on Earth and Beyond”, The Astrophysical Journal, 910(2), 85. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [7]     Aartsen M. G. et al., 2020, “eV-Scale Sterile Neutrino Search Using Eight Years of Atmospheric Muon Neutrino Data from the IceCube Neutrino Observatory”, Physical Review Letters, 125(14), 141801. (SCIE) (IF: 9.161; SCI ranking: 8.1%)
  
  
• [8]     Riehn Felix, Engel Ralph, Fedynitch Anatoli, Gaisser Thomas K., Stanev Todor, 2020, “Hadronic interaction model sibyll 2.3d and extensive air showers”, Physical Review D, 102(6), 063002. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [9]     Rudolph Annika, Heinze Jonas, Fedynitch Anatoli, Winter Walter, 2020, “Impact of the Collision Model on the Multi-messenger Emission from Gamma-Ray Burst Internal Shocks”, The Astrophysical Journal, 893(1), 72. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [10]     Bhatt Maulik, Sushch Iurii, Pohl Martin, Fedynitch Anatoli, Das Samata, Brose Robert, Plotko Pavlo, Meyer Dominique M.-A., 2020, “Production of secondary particles in heavy nuclei interactions in supernova remnants”, Astroparticle Physics, 123, 102490. (SCIE) (IF: 2.724; SCI ranking: 44.1%,44.8%)
  
  
• [11]     Aartsen M. G. et al., 2020, “Searching for eV-scale sterile neutrinos with eight years of atmospheric neutrinos at the IceCube Neutrino Telescope”, Physical Review D, 102(5), 052009. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [12]     Heinze J, Biehl D, Fedynitch A, Boncioli D, Rudolph A, Winter W, 2020, “Systematic parameter space study for the UHECR origin from GRBs in models with multiple internal shocks”, Monthly Notices of the Royal Astronomical Society, 498(4), 5990-6004. (SCIE) (IF: 5.287; SCI ranking: 23.5%)
  
  
• [13]     Heinze Jonas, Fedynitch Anatoli, Boncioli Denise, Winter Walter, 2019, “A New View on Auger Data and Cosmogenic Neutrinos in Light of Different Nuclear Disintegration and Air-shower Models”, The Astrophysical Journal, 873(1), 88. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [14]     Fedynitch Anatoli, Riehn Felix, Engel Ralph, Gaisser Thomas K., Stanev Todor, 2019, “Hadronic interaction model sibyll 2.3c and inclusive lepton fluxes”, Physical Review D, 100(10), 103018. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [15]     Palladino Andrea, Fedynitch Anatoli, Rasmussen Rasmus W., Taylor Andrew M., 2019, “IceCube neutrinos from hadronically powered gamma-ray galaxies”, Journal of Cosmology and Astroparticle Physics, 2019(09), 004-004. (SCIE) (IF: 5.839; SCI ranking: 16.2%,13.8%)
  
  
• [16]     Morejon L., Fedynitch A., Boncioli D., Biehl D., Winter W., 2019, “Improved photomeson model for interactions of cosmic ray nuclei”, Journal of Cosmology and Astroparticle Physics, 2019(11), 007-007. (SCIE) (IF: 5.839; SCI ranking: 16.2%,13.8%)
  
  
• [17]     Rodrigues Xavier, Gao Shan, Fedynitch Anatoli, Palladino Andrea, Winter Walter, 2019, “Leptohadronic Blazar Models Applied to the 2014–2015 Flare of TXS 0506+056”, The Astrophysical Journal, 874(2), L29. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [18]     Biehl D., Boncioli D., Fedynitch A., Winter W., 2018, “Cosmic ray and neutrino emission from gamma-ray bursts with a nuclear cascade”, Astronomy & Astrophysics, 611, A101.
  
  
• [19]     Gao Shan, Fedynitch Anatoli, Winter Walter, Pohl Martin, 2018, “Modelling the coincident observation of a high-energy neutrino and a bright blazar flare”, Nature Astronomy, 3(1), 88-92. (SCIE) (IF: 14.437; SCI ranking: 5.9%)
  
  
• [20]     Rodrigues Xavier, Fedynitch Anatoli, Gao Shan, Boncioli Denise, Winter Walter, 2018, “Neutrinos and Ultra-high-energy Cosmic-ray Nuclei from Blazars”, The Astrophysical Journal, 854(1), 54. (SCIE) (IF: 5.877; SCI ranking: 14.7%)
  
  
• [21]     Biehl Daniel, Fedynitch Anatoli, Palladino Andrea, Weiler Tom J., Winter Walter, 2017, “Astrophysical neutrino production diagnostics with the Glashow resonance”, Journal of Cosmology and Astroparticle Physics, 2017(01), 033-033. (SCIE) (IF: 5.839; SCI ranking: 16.2%,13.8%)
  
  
• [22]     Boncioli Denise, Fedynitch Anatoli, Winter Walter, 2017, “Nuclear Physics Meets the Sources of the Ultra-High Energy Cosmic Rays”, Scientific Reports, 7(1), 4882. (SCIE) (IF: 4.38; SCI ranking: 23.3%)
  
  
• [23]     Argüelles C.A., de Wasseige G., Fedynitch A., Jones B.J.P., 2017, “Solar atmospheric neutrinos and the sensitivity floor for solar dark matter annihilation searches”, Journal of Cosmology and Astroparticle Physics, 2017(07), 024-024. (SCIE) (IF: 5.839; SCI ranking: 16.2%,13.8%)
  
  
• [24]     Aartsen M.G. et al., 2016, “Characterization of the atmospheric muon flux in IceCube”, Astroparticle Physics, 78, 1-27. (SCIE) (IF: 2.724; SCI ranking: 44.1%,44.8%)
  
  
• [25]     Aartsen M. G. et al., 2015, “Atmospheric and astrophysical neutrinos above 1 TeV interacting in IceCube”, Physical Review D, 91(2), 022001. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [26]     Fedynitch A., Krasny M.W., Płaczek W., 2015, “Background to Higgs-boson Searches from Internal Conversions of Off-shell Photons Associated with -boson Production at the LHC”, Acta Physica Polonica B, 46(5), 983. (SCIE) (IF: 0.748; SCI ranking: 87.2%)
  
  
• [27]     Aartsen M. G. et al., 2015, “Evidence for Astrophysical Muon Neutrinos from the Northern Sky with IceCube”, Physical Review Letters, 115(8), 081102. (SCIE) (IF: 9.161; SCI ranking: 8.1%)
  
  
• [28]     Aartsen M. G. et al., 2014, “Observation of High-Energy Astrophysical Neutrinos in Three Years of IceCube Data”, Physical Review Letters, 113(10), 101101. (SCIE) (IF: 9.161; SCI ranking: 8.1%)
  
  
• [29]     M. G. Aartsen et al., 2013, “Evidence for High-Energy Extraterrestrial Neutrinos at the IceCube Detector”, Science, 342(6161), 1242856. (SCIE) (IF: 47.728; SCI ranking: 2.7%)
  
  
• [30]     Abbasi R. et al., 2013, “Lateral distribution of muons in IceCube cosmic ray events”, Physical Review D, 87(1), 012005. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [31]     Fedynitch Anatoli, Becker Tjus Julia, Desiati Paolo, 2012, “Influence of hadronic interaction models and the cosmic ray spectrum on the high energy atmospheric muon and neutrino flux”, Physical Review D, 86(11), 114024. (SCIE) (IF: 5.296; SCI ranking: 22.1%,20.7%)
  
  
• [32]     Abbasi R. et al., 2010, “The energy spectrum of atmospheric neutrinos between 2 and 200 TeV with the AMANDA-II detector”, Astroparticle Physics, 34(1), 48-58. (SCIE) (IF: 2.724; SCI ranking: 44.1%,44.8%)
  
  
• [33]     Hsiu-Hsien Lin et al., Unpublished, “BURSTT: Bustling Universe Radio Survey Telescope for Taiwan”, PUBLICATIONS OF THE ASTRONOMICAL SOCIETY OF THE PACIFIC. (SCIE) (IF: 5.445; SCI ranking: 20.6%)