O. Fedorov
Irkutsk State University
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Featured researches published by O. Fedorov.
Physics Letters B | 2016
W.D. Apel; J.C. Arteaga-Velázquez; L. Bähren; P. Bezyazeekov; K. Bekk; M. Bertaina; Peter L. Biermann; J. Blümer; H. Bozdog; I.M. Brancus; N. M. Budnev; E. Cantoni; A. Chiavassa; K. Daumiller; V. de Souza; F. Di Pierro; P. Doll; R. Engel; H. Falcke; O. Fedorov; B. Fuchs; H. Gemmeke; O. Gress; C. Grupen; A. Haungs; D. Heck; R. Hiller; J.R. Hörandel; A. Horneffer; D. Huber
Abstract The radio technique is a promising method for detection of cosmic-ray air showers of energies around 100 PeV and higher with an array of radio antennas. Since the amplitude of the radio signal can be measured absolutely and increases with the shower energy, radio measurements can be used to determine the air-shower energy on an absolute scale. We show that calibrated measurements of radio detectors operated in coincidence with host experiments measuring air showers based on other techniques can be used for comparing the energy scales of these host experiments. Using two approaches, first via direct amplitude measurements, and second via comparison of measurements with air shower simulations, we compare the energy scales of the air-shower experiments Tunka-133 and KASCADE-Grande, using their radio extensions, Tunka-Rex and LOPES, respectively. Due to the consistent amplitude calibration for Tunka-Rex and LOPES achieved by using the same reference source, this comparison reaches an accuracy of approximately 10 % – limited by some shortcomings of LOPES, which was a prototype experiment for the digital radio technique for air showers. In particular we show that the energy scales of cosmic-ray measurements by the independently calibrated experiments KASCADE-Grande and Tunka-133 are consistent with each other on this level.
arXiv: Instrumentation and Methods for Astrophysics | 2017
D. Kostunin; P. Bezyazeekov; N. M. Budnev; O. Fedorov; O. Gress; A. Haungs; R. Hiller; T. Huege; Y. Kazarina; M. Kleifges; E. E. Korosteleva; O. Krömer; V. Kungel; L. Kuzmichev; N. Lubsandorzhiev; R. R. Mirgazov; R. Monkhoev; E. Osipova; A. Pakhorukov; L. Pankov; V. Prosin; G. Rubtsov; F.G. Schröder; R. Wischnewski; A. Zagorodnikov
The Tunka Radio Extension (Tunka-Rex) is a radio detector at the TAIGA facility located in Siberia nearby the southern tip of Lake Baikal. Tunka-Rex measures air-showers induced by high-energy cosmic rays, in particular, the lateral distribution of the radio pulses. The depth of the air-shower maximum, statistically depends on the mass of the primary particle, is determined from the slope of the lateral distribution function (LDF). Using a model-independent approach, we have studied possible features of the one-dimensional slope method and tried to find improvements for the reconstruction of primary mass. To study the systematic uncertainties given by different primary particles, we have performed simulations using the CONEX and CoREAS software packages of the recently released CORSIKA v7.5 including the modern high-energy hadronic models QGSJet-II.04 and EPOS-LHC. The simulations have shown that the largest systematic uncertainty in the energy deposit is due to the unknown primary particle. Finally, we studied the relation between the polarization and the asymmetry of the LDF.
Journal of Physics: Conference Series | 2016
Nikolay M. Budnev; I. I. Astapov; P. Bezyazeekov; A. G. Bogdanov; V. Boreyko; M Büker; M. Brückner; A. Chiavassa; O. Chvalaev; O. Gress; T. Gress; O. Grishin; A. Dyachok; S. Epimakhov; O. Fedorov; Aleksandr Gafarov; N. Gorbunov; V. Grebenyuk; A. Grinuk; A. Haungs; R. Hiller; D. Horns; T. Huege; A. Ivanova; A Kalinin; N. Karpov; N. N. Kalmykov; Y. Kazarina; N. Kirichkov; S. Kiryuhin
The physical motivations and advantages of the new gamma-observatory TAIGA (Tunka Advanced Instrument for cosmic ray physics and Gamma Astronomy) is presented. The TAIGA array is a complex, hybrid detector for ground-based gamma-ray astronomy for energies from a few TeV to several PeV as well as for cosmic ray studies from 100 TeV to several EeV. The TAIGA will include the wide angle Cherenkov array TAIGA-HiSCORE with ~5 km2 area, a net of 16 I ACT telescopes (with FOV of about 10x10 degree), muon detectors with a total area of up to 2000-3000 m2 and the radio array Tunka-Rex.
Journal of Instrumentation | 2017
N. M. Budnev; I. I. Astapov; P. Bezyazeekov; V. Boreyko; A. Borodin; M. Brückner; A. Chiavassa; Aleksandr Gafarov; V. Grebenyuk; O. Gress; T. Gress; A. Grinyuk; O. Grishin; A. Dyachok; O. Fedorov; A. Haungs; D. Horns; T. Huege; A. Ivanova; N. N. Kalmykov; Y. Kazarina; V. V. Kindin; S. Kiryuhin; R. P. Kokoulin; K. G. Kompaniets; D. Kostunin; E. E. Korosteleva; V. Kozhin; E. A. Kravchenko; M. Kunnas
The TAIGA observatory addresses ground-based gamma-ray astronomy at energies from a few TeV to several PeV, as well as cosmic ray physics from 100 TeV to several EeV . TAIGA will be located in the Tunka valley, ~ 50 km West from Lake Baikal. The different detectors of the TAIGA will be grouped in 6 arrays to measure Cherenkov and radio emission as well as electron and muon components of atmospheric showers. The combination of the wide angle Cherenkov detectors of the TAIGA-HiSCORE array and the 4-m Imaging Atmospheric Cherenkov Telescopes of the TAIGA-IACT array with their FoV of 10×10 degrees and underground muon detectors offers a very cost effective way to construct a 5 km2 array for gamma-ray astronomy.
Bulletin of The Russian Academy of Sciences: Physics | 2017
R. Monkhoev; N. M. Budnev; D. M. Voronin; Aleksandr Gafarov; O. Gress; T. Gress; O. G. Grishin; A. Dyachok; S. N. Epimakhov; D. Zhurov; A. Zagorodnikov; V. L. Zurbanov; A. Ivanova; N. N. Kalmykov; Y. Kazarina; S. Kiryuhin; E. E. Korosteleva; V. Kozhin; L. A. Kuzmichev; V. Lenok; B. Lubsandorzhiev; N. B. Lubsandorzhiev; R. R. Mirgazov; R. Mirzoyan; E. Osipova; A. Pakhorukov; M. I. Panasyuk; L. Pankov; V. Poleschuk; E. Popova
The Tunka-Grande scintillation array is described. The first results from its operation are presented. The prospects for studying primary cosmic rays in the energy range of 1016 to 1018 eV during simultaneous registration of the Cherenkov and charged particle components along with radio emissions from extensive air showers are discussed.
Physics of Particles and Nuclei | 2018
Nikolay M. Budnev; I. I. Astapov; P. Bezyazeekov; A. V. Boreyko; A. Borodin; A. Yu. Garmash; Aleksandr Gafarov; N. Gorbunov; V. Grebenyuk; O. Gress; T. Gress; A. Grinyuk; O. G. Grishin; A. Dyachok; D. Zhurov; A. Zagorodnikov; V. L. Zurbanov; A. Ivanova; Y. Kazarina; N. N. Kalmykov; V. V. Kindin; P. Kirilenko; S. Kiryuhin; V. Kozhin; R. P. Kokoulin; K. G. Kompaniets; E. E. Korosteleva; D. Kostunin; E. Kravchenko; L. A. Kuzmichev
The article presents the relevance and advantages of the new gamma observatory TAIGA (Tunka Advanced Instrument for cosmic ray physics and Gamma Astronomy), which is being constructed in the Tunka Valley 50 km from Lake Baikal. Various detectors of the six TAIGA gamma observatory arrays register the Cherenkov and radio radiation, as well as the electron and muon components of EAS. The primary objective of the TAIGA gamma observatory is to study the high-energy part of the gamma-ray spectrum, in particular, in order to search for Galactic PeVatrons. The energy, direction, and position of the EAS axis are reconstructed in the observatory based on the data of the wide-angle Cherenkov detectors of the TAIGA-HiSCORE experiment. Taking into account this information, the gamma quanta are distinguished from the hadron background using the data obtained by the muon detectors and telescopes that register the EAS image in the Cherenkov light. In this hybrid mode of operation, the atmospheric Cherenkov telescopes can operate in the mono-mode, and the distance between them can be increased to 800–1000 m, which makes it possible to construct an array with an area of 5 km2 and more at relatively low cost and in a short time. By 2019, the first stage of the gamma observatory with an area of 1 km2 will be constructed; its expected integral sensitivity for detecting the gamma radiation with an energy of 100 TeV at observation of the source for 300 hours will be approximately
Physics of Atomic Nuclei | 2018
L. A. Kuzmichev; I. I. Astapov; P. Bezyazeekov; V. Boreyko; A. Borodin; Nikolay M. Budnev; R. Wischnewski; A. Garmash; Aleksandr Gafarov; N. Gorbunov; V. Grebenyuk; O. Gress; T. Gress; A. Grinyuk; O. G. Grishin; A. Dyachok; A. Zagorodnikov; V. L. Zurbanov; A. Ivanova; Y. Kazarina; N. N. Kalmykov; N. I. Karpov; V. V. Kindin; P. Kirilenko; S. Kiryuhin; V. Kozhin; R. P. Kokoulin; K. G. Kompaniets; E. E. Korosteleva; E. A. Kravchenko
arXiv: High Energy Astrophysical Phenomena | 2017
F.G. Schröder; P. Bezyazeekov; N. M. Budnev; O. Fedorov; O. Gress; A. Haungs; R. Hiller; T. Huege; Y. Kazarina; M. Kleifges; E. E. Korosteleva; D. Kostunin; O. Krömer; V. Kungel; L. Kuzmichev; N. Lubsandorzhiev; R. R. Mirgazov; R. Monkhoev; E. Osipova; A. Pakhorukov; L. Pankov; V. Prosin; G. Rubtsov; R. Wischnewski; A. Zagorodnikov
2 times 5
Proceedings of 35th International Cosmic Ray Conference — PoS(ICRC2017) | 2017
R. Wischnewski; A. Porelli; A. Garmash; I. I. Astapov; P. Bezyazeekov; V. Boreyko; A. Borodin; M. Brueckner; N. M. Budnev; A. Chiavassa; A. Dyachok; O. Fedorov; Aleksandr Gafarov; N. Gorbunov; E. Gorbovskoy; Victor Grebenyuk; O. Gress; T. Gress; O. Grishin; A. Grinyuk; D. Horns; A. Ivanova; N. N. Kalmykov; Y. Kazarina; V. V. Kindin; P. Kirilenko; S. Kiryuhin; R. P. Kokoulin; K. G. Kompaniets; E. E. Korosteleva
Proceedings of 35th International Cosmic Ray Conference — PoS(ICRC2017) | 2017
F.G. Schröder; N. M. Budnev; Daria Chernykh; O. Fedorov; O. Gress; A. Haungs; R. Hiller; Tim Huege; Y. Kazarina; M. Kleifges; E. E. Korosteleva; D. Kostunin; O. Krömer; Leonid Kuzmichev; V. Lenok; N. Lubsandorzhiev; Tatiana Marshalkina; R. R. Mirgazov; R. Monkhoev; Eleonora Osipova; A. Pakhorukov; L. Pankov; V. Prosin; A. Zagorodnikov; P. Bezyazeekov
n 10–13 TeV cm–2s–1.
