Inferences on mass composition and tests of hadronic interactions from 0.3 to 100 EeV using the water-Cherenkov detectors of the Pierre Auger Observatory

Aab, A.; Abreu, P.; Aglietta, M.; Samarai, I. Al; Albuquerque, I. F. M.; Allekotte, I.; Almela, A.; Castillo, J.; Álvarez-Muñiz, J.; Anastasi, Gioacchino Alex; Anchordoqui, Luis A.; Andrada, Belén; Andringa, S.; Aramo, C.; Arqueros, F.; Arsene, N.; Asorey, H.; Assis, P.; Aublin, J.; Ávila, G.; Badescu, A. M.; Bălăceanu, Alexandru; Barbato, Felicia; Luz, Ricardo Jorge Barreira; Beatty, J. J.; Becker, Karl‐Heinz; Bellido, J. A.; Bérat, C.; Bertaina, M.; Bertou, X.; Biermann, Peter L.; Biteau, J.; Blaess, S. G.; Blanco, A.; Blažek, Jiří; Bleve, C.; Bohã̌cov́a, M.; Boncioli, D.; Bonifazi, C.; Borodai, N.; Botti, Ana Martina; Brack, Jeffrey; Brancus, I. M.; Bretz, T.; Bridgeman, A.; Briechle, Florian Lukas; Buchholz, P.; Bueno, A.; Buitink, S.; Buscemi, Mario; Caballero-Mora, K. S.; Caccianiga, Lorenzo; Cancio, A.; Canfora, F.; Caramete, L.; Caruso, R.; Castellina, A.; Catalani, Fernando; Cataldi, G.; Cazón, L.; Chavez, A. G.; Chinellato, J. A.; Chudoba, J.; Clay, R. W.; Cobos, A.; Colalillo, R.; Coleman, Alan; Collica, L.; Coluccia, M. R.; Conceição, R.; Consolati, G.; Contreras, F.; Cooper, M. J.; Coutu, S.; Covault, C. E.; Cronin, J. W.; D’Amico, S.; Daniel, B.; Dasso, S.; Daumiller, K.; Dawson, B. R.; Almeida, R. M. de; Jong, S. J. De; Mauro, G. De; Neto, J. R. T. de Mello; Mitri, I. De; Oliveira, Jaime de; Souza, Vítor de; Debatin, J.; Deligny, O.; Castro, M. L. Díaz; Diogo, F.; Dobrigkeit, C.; D’Olivo, J. C.; Dorosti, Q.; Anjos, Rita Cassia dos; Dova, M. T.; Dundovic, A.; Ebr, Jan; Engel, R.; Erdmann, M.; Erfani, Mostafa; Escobar, C. O.; Espadanal, J.; Etchegoyen, A.; Falcke, H.; Farmer, John; Farrar, Glennys R.; Fauth, A. C.; Fazzini, N.; Fenu, Francesco; Fick, B.; Figueira, J. M.; Filipčić, A.; Fratu, Octavian; Freire, M. M.; Fujii, Toshihiro; Fuster, Alan; Gaïor, R.; García, Beatriz; Garcia-Pinto, D.; Gaté, F.; Gemmeke, H.; Gherghel-Lascu, A.; Ghia, P. L.; Giaccari, U.; Giammarchi, M.; Giller, M.; Głas, D.; Gläser, Christian; Golup, G.; Berisso, M. Gómez; Vitale, Primo F. Gómez; González, Nicolás Martín; Gorgi, A.; Gorham, P. W.; Grillo, A. F.; Grubb, Trent D.; Guarino, F.; Guedes, G. P.; Halliday, R.; Hampel, Matías Rolf; Hansen, P.; Harari, D.; Harrison, T. A.; Harton, J. L.; Haungs, A.; Hebbeker, T.; Heck, D.; Heimann, P.; Hervé, A. E.; Hill, G. C.; Hojvat, C.; Holt, E.; Homola, P.; Hörandel, J. R.; Horváth, P.; Hrabovský, M.; Huege, T.; Hulsman, J.; Insolia, A.; Isar, P. G.; Jandt, I.; Johnsen, Jeffrey A.; Josebachuili, M.; Jurýšek, Jakub; Kääpä, Alex; Kambeitz, O.; Kampert, Karl-Heinz; Keilhauer, B.; Kemmerich, N.; Kemp, E.; Kemp, J.; Kieckhafer, R. M.; Klages, H. O.; Kleifges, M.; Kleinfeller, J.; Krause, R.; Krohm, N.; Kuempel, D.; Mezek, G. Kukec; Kunka, N.; Awad, A. Kuotb; Lago, Bruno L.; LaHurd, D.; Lang, Rodrigo Guedes; Lauscher, M.; Legumina, R.; Oliveira, M. A. Leigui de; Letessier‐Selvon, A.; Lhenry-Yvon, I.; Link, K.; Presti, Domenico Lo; Lopes, L.; López, R.; Casado, A. López; Lorek, R.; Luce, Quentin; Lucero, A.; Malacari, M.; Mallamaci, M.; Mandát, Dušan; Mantsch, P.; Mariazzi, A. G.; Maris, Ioana Codrina; Marsella, G.; Martello, D.; Martínez, H.; Bravo, O. Martínez; Meza, J. J. Masías; Mathes, H. J.; Mathys, S.; Matthews, John; Matthiae, G.; Mayotte, E.; Mazur, Péter; Medina, C.; Medina‐Tanco, G.; Melo, D.; Menshikov, Alexander; Merenda, Kevin-Druis; Michal, Stanislav; Micheletti, M. I.; Middendorf, L.; Miramonti, L.; Mitrica, B.; Mockler, D.; Mollerach, Silvia; Montanet, F.; Morello, C.; Mostafá, M.; Müller, Ana L.; Müller, G.; Müller, M. A.; Müller, S.; Mussa, R.; Naranjo, I. N.; Nellen, Lukas; Nguyen, P.; Niculescu-Oglinzanu, M.; Niechciol, Marcus; Niemietz, L.; Niggemann, T.; Nitz, D.; Nosek, D.; Novotný, Vladimír; Nožka, L.; Núñez, Luis A.; Ochilo, L.; Oikonomou, Foteini; Olinto, Angela V.; Palatka, M.; Pallotta, J.; Papenbreer, P.; Parente, G.; Parra, A.; Paul, T.; Pech, M.; Pedreira, F.; Pękala, Jan; Pelayo, R.; Peña-Rodríguez, Jesús; Pereira, L. A. S.; Perlín, M.; Perrone, L.; Peters, C. F. W.; Petrera, S.; Phuntsok, J.; Piegaia, R.; Pierog, T.; Pimenta, M.; Pirronello, V.; Platino, M.; Plum, M.; Porowski, C.; Prado, R. R.; Privitera, P.; Prouza, M.; Quel, E. J.; Querchfeld, S.; Quinn, S.; Ramos-Pollán, Raúl; Rautenberg, J.; Ravignani, D.; Řídký, J.; Riehn, Felix; Risse, M.; Ristori, P.; Rizi, Vincenzo; Carvalho, W. Rodrigues de; Fernandez, G. Rodriguez; Rojo, Juan; Rogozin, D.; Roncoroni, Matías J.; Roth, M.; Roulet, Esteban; Rovero, A. C.; Ruehl, Philip; Saffi, S. J.; Sǎftoiu, A.; Salamida, F.; Salazar, H.; Saleh, A.; Greus, F. Salesa; Salina, G.; Sánchez, F.; Sánchez-Lucas, P.; Santos, Eva; Santos, Edivaldo Moura; Sarazin, F.; Sarmento, R.; Sarmiento-Cano, C.; Sato, R.; Schauer, Markus; Scherini, V.; Schieler, H.; Schimp, Michael; Schmidt, D.; Scholten, Olaf; Schovánek, Petr; Schröder, Frank G.; Schröder, S.; Schulz, Alexander; Schumacher, J.; Sciutto, S. J.; Segreto, A.; Shadkam, A.; Shellard, R. C.; Sigl, Guenter; Silli, Gaia; Sima, O.; Śmiałkowski, A.; Šmída, R.; Smith, B. E.; Snow, G. R.; Sommers, P.; Sonntag, S.; Squartini, R.; Stanca, Denis; Stanič, S.; Stasielak, J.; Stassi, P.; Stolpovskiy, M.; Strafella, F.; Streich, Alexander; Suárez, F.; Durán, M. Suarez; Sudholz, T.; Suomijärvi, T.; Supanitsky, A. D.; Šupík, J.; Swain, J.; Szadkowski, Z.; Taboada, A.; Taborda, O. A.; Theodoro, V. M.; Timmermans, C.; Peixoto, C. J. Todero; Tomankova, L.; Tomé, B.; Elipe, G. Torralba; Trávničék, P.; Trini, M.; Ulrich, R.; Unger, Michael; Urban, M.; Galicia, J. F. Valdés; Valiño, I.; Valore, L.; Aar, G. van; Bodegom, Peter M. van; Berg, A. M. van den; Vliet, A. van; Varela, E.; Cárdenas, B. Vargas; Varner, G.; Vázquez, R. A.; Veberič, D.; Ventura, Cynthia; Quispe, Indira D. Vergara; Verzi, V.; Vícha, J.; Villaseñor, L.; Vorobiov, S.; Wahlberg, H.; Wainberg, O.; Walz, D.; Watson, Alan; Weber, M.; Weindl, A.; Wiencke, L.; Wilczyński, H.; Wileman, C.; Wirtz, Marcus; Wittkowski, David; Wundheiler, B.; Yang, Lili; Yushkov, A.; Zas, E.; Zavrtanik, D.; Zavrtanik, M.; Zepeda, A.; Zimmermann, B.; Ziolkowski, M.; Zong, Z.; Zuccarello, F.

doi:10.1103/physrevd.96.122003

Cited by 118 publications

(107 citation statements)

References 23 publications

(33 reference statements)

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“…Phenomenologically, it is interesting to investigate whether such an additional component may better describe the Auger data and whether such a component can be ruled out by multimessenger data. Further motivation to study an additional UHE light component comes from recent observational evidence using Augers surface detector (SD), which shows that the rate of increase of the average nuclear mass with energy is slowing at the highest energies [58]. That analysis makes use of the fact that the SD rise-time is sensitive to composition and that the order-of-magnitude larger SD dataset provides adequate statistics to study trends to higher energies than is possible with the fluorescence detectors measurements of X max .…”

Section: B Subdominant Pure-proton Componentmentioning

confidence: 99%

Progress towards characterizing ultrahigh energy cosmic ray sources

2019

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We use a multimessenger approach to constrain realistic mixed composition models of ultrahigh energy cosmic ray sources using the latest cosmic ray, neutrino, and gamma-ray data. We build on the successful Unger-Farrar-Anchordoqui 2015 (UFA15) model which explains the shape of the spectrum and its complex composition evolution via photodisintegration of accelerated nuclei in the photon field surrounding the source. We explore the constraints which can currently be placed on the redshift evolution of sources and the temperature of the photon field surrounding the sources. We show that a good fit is obtained to all data either with a source which accelerates a narrow range of nuclear masses or a Milky Way-like mix of nuclear compositions, but in the latter case the nearest source should be 30-50 Mpc away from the Milky Way in order to fit observations from the Pierre Auger Observatory. We also ask whether the data allow for a subdominant purely protonic component at UHE in addition to the primary UFA15 mixed composition component. We find that such a two-component model can significantly improve the fit to cosmic ray data while being compatible with current multimessenger data.

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Section: B Subdominant Pure-proton Componentmentioning

confidence: 99%

Progress towards characterizing ultrahigh energy cosmic ray sources

2019

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“…The measurements by Auger indicate that the depth of the shower maximum (X max ) -a proxy for the composition -favors the interpretation of a very light composition at ∼ 2 EeV, dominated by protons, with the average mass composition increasing with energy after that. This increase seems to stop, however, at an energy of ∼ 50 EeV [9], which might be an indication for a subdominant light component at these energies. TA's measurements of X max are compatible with the results found by Auger within uncertainties [10].…”

mentioning

confidence: 91%

Determining the fraction of cosmic-ray protons at ultrahigh energies with cosmogenic neutrinos

2019

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Cosmogenic neutrinos are produced when ultra-high-energy cosmic rays (UHECRs) interact with cosmological photon fields. Limits on the diffuse flux of these neutrinos can be used to constrain the fraction of protons arriving at Earth with energies Ep 30 EeV, thereby providing bounds on the composition of UHECRs without fully relying on hadronic interaction models. We show to which extent current neutrino telescopes already constrain this fraction of protons and discuss the prospects for next-generation detectors to further constrain it. Additionally, we discuss the implications of these limits for several popular candidates for UHECR source classes.

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“…As for ultra-high-energy cosmic rays (UHECRs) with energies between ∼10 18 and ∼10 20 eV, their sources and acceleration mechanism remain much less clear. The Pierre Auger Observatory has enabled a better understanding of the UHECR spectrum by showing evidence that the highest-energy bins should contain nuclei heavier than hydrogen and helium (Aab et al 2014a(Aab et al , 2014b(Aab et al , 2017aAbbasi et al 2016). While at ∼10 18 eV the composition is proton only, at ∼3×10 19 eV the UHECR composition is nitrogen-like, outlining a scenario where the UHECR composition becomes heavier as the energy increases, with a possible contribution from iron close to the highest-energy cutoff (Dembinski et al 2019;Heinze et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Bottom-up Acceleration of Ultra-high-energy Cosmic Rays in the Jets of Active Galactic Nuclei

Mbarek

Caprioli

2019

ApJ

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It has been proposed that ultra-high-energy cosmic rays (UHECRs) up to 10 20 eV could be produced in the relativistic jets of powerful active galactic nuclei (AGNs) via a one-shot reacceleration of lower-energy CRs produced in supernova remnants (the espresso mechanism). We test this theory by propagating particles in realistic 3D magnetohydrodynamic simulations of ultrarelativistic jets and find that about 10% of the CRs entering the jet are boosted by at least a factor of ∼Γ 2 in energy, where Γ is the jet's effective Lorentz factor, in agreement with the analytical expectations. Furthermore, about 0.1% of the CRs undergo two or more shots and achieve boosts well in excess of Γ 2 . Particles are typically accelerated up to the Hillas limit, suggesting that the espresso mechanism may promote galactic-like CRs to UHECRs even in AGN jets with moderate Lorentz factors, and not in powerful blazars only. Finally, we find that the sign of the toroidal magnetic field in the jet and in the cocoon controls the angular distribution of the reaccelerated particles, leading to a UHECR emission that may be either quasi-isotropic or beamed along the jet axis. These findings strongly support the idea that espresso acceleration in AGN jets can account for the UHECR spectra, chemical composition, and arrival directions measured by Auger and Telescope Array.

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Inferences on mass composition and tests of hadronic interactions from 0.3 to 100 EeV using the water-Cherenkov detectors of the Pierre Auger Observatory

Cited by 118 publications

References 23 publications

Progress towards characterizing ultrahigh energy cosmic ray sources

Progress towards characterizing ultrahigh energy cosmic ray sources

Determining the fraction of cosmic-ray protons at ultrahigh energies with cosmogenic neutrinos

Bottom-up Acceleration of Ultra-high-energy Cosmic Rays in the Jets of Active Galactic Nuclei

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