Constraints on the emission region of 3C 279 during strong flares in 2014 and 2015 through VHE <i>γ</i>-ray observations with H.E.S.S.

Abdalla, H.; Adam, R.; Aharonian, F.; Benkhali, F. Ait; Angüner, E. O.; Arakawa, M.; Arcaro, C.; Armand, Céline; Ashkar, Halim; Backes, Michael; Martins, Victor Barbosa; Barnard, M.; Becherini, Y.; Berge, D.; Bernlöhr, K.; Blackwell, R.; Böttcher, M.; Boisson, C.; Bolmont, J.; Bonnefoy, S.; Bregeon, J.; Breuhaus, M.; Brun, F.; Brun, P.; Bryan, M.; Büchele, M.; Bulik, T.; Bylund, T.; Capasso, M.; Caroff, S.; Carosi, A.; Casanova, S.; Cerruti, M.; Chand, T.; Chandra, S.; Chen, A.; Colafrancesco, S.; Curyło, M.; Davids, I. D.; Deil, C.; Devin, J.; deWilt, P.; Dirson, L.; Djannati‐Ataï, A.; Dmytriiev, A.; Donath, Axel; Doroshenko, V.; Drury, L. O’c.; Dyks, J.; Egberts, K.; Emery, Gabriel; Ernenwein, J.-P.; Eschbach, S.; Feijen, Kirsty; Fegan, S. J.; Fiaßon, A.; Fontaine, G.; Funk, Stefan; Füßling, M.; Gabici, S.; Gallant, Y. A.; Gaté, F.; Giavitto, G.; Glawion, D.; Glicenstein, J. F.; Gottschall, D.; Grondin, M.‐H.; Hahn, Joachim; Haupt, M.; Heinzelmann, G.; Henri, G.; Hermann, G.; Hinton, Jim; Hofmann, W.; Hoischen, C.; Holch, T. L.; Holler, M.; Horns, D.; Huber, David Miles; Iwasaki, H.; Jamrozy, M.; Jankowsky, D.; Jankowsky, F.; Jardin-Blicq, A.; Jung-Richardt, I.; Kastendieck, M. A.; Katarzyński, K.; Katsuragawa, M.; Katz, U.; Khangulyan, D.; Khélifi, B.; King, Johannes; Klepser, S.; Kluźniak, W.; Komin, Nu.; Kosack, K.; Kostunin, D.; Kraus, Martin; Lamanna, G.; Lau, J.; Lemière, A.; Lemoine‐Goumard, M.; Lenain, J.-P.; Leser, E.; Levy, C.; Löhse, T.; Lypova, I.; Mackey, Jonathan; Majumdar, Jhilik; Malyshev, D.; Marandon, V.; Marcowith, A.; Mares, Arnaud; Mariaud, C.; Martí-Devesa, G.; Marx, R.; Maurin, G.; Meintjes, P. J.; Mitchell, Alison; Moderski, R.; Mohamed, M.; Mohrmann, L.; Moore, C. J.; Moulin, Emmanuel; Müller, J.; Murach, T.; Nakashima, Shinya; Naurois, M. de; Ndiyavala, H.; Niederwanger, F.; Niemiec, J.; Oakes, L.; O’Brien, P. T.; Odaka, Hirokazu; Ohm, S.; Wilhelmi, E. de Oña; Ostrowski, M.; Oya, I.; Panter, M.; Parsons, R. D.; Perennes, C.; Petrucci, P.-O.; Peyaud, B.; Piel, Q.; Pita, S.; Poireau, V.; Noel, A. Priyana; Prokhorov, Dmitry; Prokoph, H.; Pühlhofer, G.; Punch, M.; Quirrenbach, A.; Raab, S.; Rauth, R.; Reimer, O.; Remy, Quentin; Renaud, M.; Rieger, F.; Rinchiuso, L.; Romoli, C.; Rowell, G.; Rudak, B.; Ruiz-Velasco, E.; Sahakian, V.; Saito, Shinya; Sánchez, David; Santangelo, A.; Sasaki, M.; Schlickeiser, R.; Schüßler, F.; Schulz, A.; Schutte, H. M.; Schwanke, U.; Schwemmer, S.; Seglar-Arroyo, M.; Senniappan, M.; Seyffert, A. S.; Shafi, N.; Shiningayamwe, K.; Simoni, R.; Sinha, Atreyee; Sol, H.; Specovius, A.; Spir-Jacob, Marion; Stawarz, Ł.; Steenkamp, R.; Stegmann, C.; Steppa, C.; Takahashi, Tadayuki; Tavernier, T.; Taylor, A. M.; Terrier, R.; Tiziani, D.; Tluczykont, M.; Trichard, C.; Tsirou, M.; Tsuji, N.; Tuffs, R.; Uchiyama, Y.; Walt, D. J. van der; Eldik, C. van; Rensburg, C. van; Soelen, B. van; Vasileiadis, G.; Veh, J.; Venter, C.; Vincent, P.; Vink, Jacco; Voisin, F.; Völk, H. J.; Vuillaume, Thomas; Wadiasingh, Zorawar; Wagner, S. J.; White, R.; Wierzcholska, A.; Yang, R.; Yoneda, Hiroki; Zacharias, M.; Zanin, R.; Zdziarski, A. A.; Zech, A.; Ziegler, Andreas; Zorn, J.; Żywucka, N.; Meyer, M.

doi:10.1051/0004-6361/201935704

Cited by 39 publications

(8 citation statements)

References 75 publications

(67 reference statements)

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“…For the target photon spectrum, we use the 3C 279 synchrotron SC spectrum model from ref. [53] (figure 7 of that work, low state), presented here in figure 2.…”

Section: Numerical Calculationmentioning

confidence: 97%

See 1 more Smart Citation

Neutrino production in blazar radio cores

Kalashev,

Kivokurtseva,

Troitsky

2023

J. Cosmol. Astropart. Phys.

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Models of the origin of astrophysical neutrinos with energies from TeVs to PeVs are strongly constrained by multimessenger observations and population studies. Recent results point to statistically significant associations between these neutrinos and active galactic nuclei (AGN) selected by their radio flux observed with very-long-baseline interferometry (VLBI). This suggests that the neutrinos are produced in central parsecs of blazars, AGN with relativistic jets pointing to the observer. However, conventional AGN models tend to explain only the highest-energy part of the neutrino flux observationally associated with blazars. Here we discuss in detail how the neutrinos can be produced in the part of an AGN giving the dominant contribution to the VLBI radio flux, the radio core located close to the jet base. Physical conditions there differ both from the immediate environment of the central black hole and from the plasma blobs moving along the jet. Required neutrino fluxes, considerably smaller than those of photons, can be produced in interactions of relativistic protons, accelerated closer to the black hole, with radiation in the core.

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“…For the target photon spectrum, we use the 3C 279 synchrotron SC spectrum model from ref. [53] (figure 7 of that work, low state), presented here in figure 2.…”

Section: Numerical Calculationmentioning

confidence: 97%

“…The simulation is performed in the core frame, so the spectrum of SSC photons of ref. [53] is converted to the photon density using eq. (2.1), and the resulting neutrino flux is converted back to the observer's frame using the inverse of eq.…”

Section: Numerical Calculationmentioning

confidence: 99%

Neutrino production in blazar radio cores

Kalashev,

Kivokurtseva,

Troitsky

2023

J. Cosmol. Astropart. Phys.

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show abstract

“…Detailed calculations including all relevant BLR lines and the thermal continuum from the disk scattered by the BLR [114,[142][143][144][145] show that the very detection of γ-ray photons with energies greater than 100 GeV from FSRQs is enough to put the location of the emitting region beyond the BLR. Observations of FSRQs at E > 100 GeV confirmed this scenario and proved that, at least for the sources that have been detected at high energies, the emitting region is at or beyond r BLR [146][147][148][149][150][151][152].…”

Section: On the Location Of The γ-Ray Emitting Region In Fsrqsmentioning

confidence: 61%

Leptonic and Hadronic Radiative Processes in Supermassive-Black-Hole Jets

Cerruti

2020

Galaxies

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Supermassive black holes lying in the center of galaxies can launch relativistic jets of plasma along their polar axis. The physics of black-hole jets is a very active research topic in astrophysics, owing to the fact that many questions remain open on the physical mechanisms of jet launching, of particle acceleration in the jet, and on the radiative processes. In this work I focus on the last item, and present a review of the current understanding of radiative emission processes in supermassive-black-hole jets.

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“…While the radius of the emission region may not expand as rapidly as the larger jet structure that surrounds it, it expands nonetheless while it travels through the jet [33] given the high energy densities in the emission region. While recent observational results [30,34] indicate compact emission regions beyond the BLR, and maybe even at tens of parsecs from the black hole, it is not clear whether these are indeed moving emission regions originating close to the black hole or turbulent cells within a larger flaring region. Similarly, while a high magnetic field can be expected close to the black hole, the expansion of the emission region causes a drop of the magnetic field with increasing distance.…”

Section: Influence Of the External Fieldsmentioning

confidence: 97%

“…The given parameter values are a toy model, which we use to perform a small parameter study. The parameters are based upon the flat spectrum radio quasar 3C 279 [30], however a direct data comparison is beyond the scope of this paper. Instead, we wish to analyze the influence of the external fields on the SED and the particle distributions.…”

Section: Influence Of the External Fieldsmentioning

confidence: 99%