Monte Carlo simulations for the Pierre Auger Observatory using the VO auger grid resources
Presented by
E. Santos* on behalf of
on behalf of the Pierre Auger Collaboration,
P. Abreu,
M. Aglietta,
J.M. Albury,
I. Allekotte,
A. Almela, J. Alvarez-Muñiz, R. Alves Batista, G.A. Anastasi, L.A. Anchordoqui, B. Andrada, S. Andringa, C. Aramo, P.R. Araújo Ferreira, J.C. Arteaga Velazquez, H.G. Asorey, P. Assis, G. Avila, A.M. Badescu, A. Bakalova, A. Balaceanu, F. Barbato, R.J. Barreira Luz, K.H. Becker, J.A. Bellido, C. Berat, M.E. Bertaina, X. Bertou, P.L. Biermann, V. Binet, K. Bismark, T. Bister, J. Biteau, J. Blazek, C. Bleve, M. Bohacova, D. Boncioli, C. Bonifazi, L. Bonneau Arbeletche, N. Borodai, A.M. Botti, J. Brack, T. Bretz, P.G. Brichetto Orchera, F.L. Briechle, P. Buchholz, A. Bueno, S. Buitink, M. Buscemi, M. Büsken, K.S. Caballero-Mora, L. Caccianiga, F. Canfora, I. Caracas, J.M. Carceller, R. Caruso, A. Castellina, F. Catalani, G. Cataldi, L. Cazon, M. Cerda, J.A. Chinellato, J. Chudoba, L. Chytka, R.W. Clay, A. Cobos Cerutti, R. Colalillo, A. Coleman, M.R. Coluccia, R. Conceição, A. Condorelli, G. Consolati, F. Contreras, F. Convenga, D. Correia dos Santos, C. Covault, S. Dasso, K. Daumiller, B.R. Dawson, J.A. Day, R.M. de Almeida, J. de Jesus, S.J. de Jong, G. De Mauro, J. de Mello Neto, I. De Mitri, J. de Oliveira, D. de Oliveira Franco, F. de Palma, V. de Souza, E. De Vito, M. del Río, O. Deligny, L. Deval, A. di Matteo, C. Dobrigkeit, J.C. D'Olivo, L.M. Domingues Mendes, R.C. dos Anjos, D. dos Santos, M.T. Dova, J. Ebr, R. Engel, I. Epicoco, M. Erdmann, C.O. Escobar, A. Etchegoyen, H. Falcke, J. Farmer, G.R. Farrar, A.C. Fauth, N. Fazzini, F. Feldbusch, F. Fenu, B. Fick, J.M. Figueira, A. Filipcic, T. Fitoussi, T. Fodran, M.M. Freire, T. Fujii, A. Fuster, C. Galea, C. Galelli, B. García, A.L. García Vegas, H. Gemmeke, F. Gesualdi, A. Gherghel-Lascu, P.L. Ghia, U. Giaccari, M. Giammarchi, J. Glombitza, F. Gobbi, F. Gollan, G. Golup, M. Gómez Berisso, P.F. Gómez Vitale, J.P. Gongora, J.M. Gonzalez, N.M. Gonzalez, I. Goos, D. Gora, A. Gorgi, M. Gottowik, T.D. Grubb, F. Guarino, G. Guedes, E. Guido, S.T. Hahn, P. Hamal, M.R. Hampel, P.M. Hansen, D. Harari, V.M. Harvey, A. Haungs, T. Hebbeker, D. Heck, G.C. Hill, C. Hojvat, J. Hörandel, P. Horvath, M. Hrabovsky, T. Huege, A. Insolia, P.G. Isar, P. Janecek, J.A. Johnsen, J. Jurysek, A. Kääpä, K.H. Kampert, N. Karastathis, B. Keilhauer, J. Kemp, A. Khakurdikar, V.V. Kizakke Covilakam, H. Klages, M. Kleifges, J. Kleinfeller, M. Köpke, N. Kunka, B.L. Lago, R.G. Lang, N. Langner, M.A. Leigui de Oliveira, V. Lenok, A. Letessier-Selvon, I. Lhenry-Yvon, D. Lo Presti, L. Lopes, R. López, L. Lu, Q. Luce, J.P. Lundquist, A. Machado Payeras, G. Mancarella, D. Mandat, B.C. Manning, J. Manshanden, P. Mantsch, S. Marafico, A. Mariazzi, I.C. Maris, G. Marsella, D. Martello, S. Martinelli, O. Martínez Bravo, M. Mastrodicasa, H.J. Mathes, J. Matthews, G. Matthiae, E.W. Mayotte, P. Mazur, G. Medina-Tanco, D. Melo, A. Menshikov, K.D. Merenda, S. Michal, M.I. Micheletti, L. Miramonti, S. Mollerach, F. Montanet, C. Morello, M. Mostafa, A.L. Müller, M.A. Muller, K. Mulrey, R. Mussa, M.S. Muzio, W.M. Namasaka, A. Nasr-Esfahani, L. Nellen, M. Niculescu-Oglinzanu, M. Niechciol, D. Nitz, D. Nosek, V. Novotný, L. Nozka, A. Nucita, L.A. Nunez, M. Palatka, J. Pallotta, P. Papenbreer, G. Parente, A. Parra, J. Pawlowsky, M. Pech, F. Pedreira, J. Pękala, R. Pelayo, J. Peña-Rodríguez, E.E. Pereira Martins, J. Perez Armand, C. Pérez Bertolli, M. Perlin, L. Perrone, S. Petrera, T. Pierog, M. Pimenta, V. Pirronello, M. Platino, B. Pont, M. Pothast, P. Privitera, M. Prouza, A. Puyleart, S. Querchfeld, J. Rautenberg, D. Ravignani, M. Reininghaus, J. Ridky, F. Riehn, M. Risse, V. Rizi, W. Rodrigues de Carvalho, J.R. Rodriguez Rojo, M.J. Roncoroni, S. Rossoni, M. Roth, E. Roulet, A. Rovero, P. Ruehl, A. Saftoiu, F. Salamida, H.I. Salazar, G. Salina, J. Sanabria Gomez, F.A. Sánchez, E.M. Santos, F. Sarazin, R. Sarmento, C. Sarmiento-Cano, R. Sato, P. Savina, C.M. Schäfer, V. Scherini, H. Schieler, M. Schimassek, M. Schimp, F. Schlüter, D. Schmidt, O. Scholten, P. Schovanek, F. Schröder, S. Schröder, J. Schulte, S.J. Sciutto, M. Scornavacche, A. Segreto, S. Sehgal, R.C. Shellard, G. Sigl, G. Silli, O. Sima, R. Smida, P. Sommers, J.F. Soriano, J. Souchard, R. Squartini, M. Stadelmaier, D. Stanca, S. Stanič, J. Stasielak, P. Stassi, A. Streich, M. Suárez-Durán, T. Sudholz, T. Suomijarvi, A.D. Supanitsky, Z. Szadkowski, A. Tapia, C. Taricco, C. Timmermans, O. Tkachenko, P. Tobiska, C.J. Todero Peixoto, B. Tomé, Z. Torrès, A. Travaini, P. Travnicek, C. Trimarelli, M.J. Tueros, R. Ulrich, M. Unger, L. Vaclavek, M. Vacula, J.F. Valdés Galicia, L. Valore, E. Varela, A. Vásquez-Ramírez, D. Veberic, C. Ventura, I.D. Vergara Quispe, V. Verzi, J. Vícha, J. Vink, S. Vorobiov, H. Wahlberg, C.K.O. Watanabe, A. Watson, M. Weber, A. Weindl, L. Wiencke, H. Wilczyński, M. Wirtz, D. Wittkowski, B. Wundheiler, A. Yushkov, O. Zapparrata, E. Zas, D. Zavrtanik, M. Zavrtanik and L. Zehreret al. (click to show)*: corresponding author
Pre-published on:
October 12, 2021
Published on:
March 18, 2022
Abstract
The Pierre Auger Observatory, located near Malargüe, Argentina, is the world's largest cosmic-ray detector.
It comprises a $3000\,\mathrm{km}^{2}$ surface detector and 27 fluorescence telescopes, which measure the lateral and longitudinal distributions of the many millions of air-shower particles produced in the interactions initiated by a cosmic ray in the Earth's atmosphere.
The determination of the nature of cosmic rays and studies of the detector performances rely on extensive Monte Carlo simulations describing the physics processes occurring in extensive air showers and the detector responses.
The aim of the Monte Carlo simulations task is to produce and provide the Auger Collaboration with reference libraries used in a
wide variety of analyses.
All multipurpose detector simulations are currently produced in local clusters using Slurm and HTCondor.
The bulk of the shower simulations are produced on the grid, via the Virtual Organization auger, using the DIRAC middleware.
The job submission is made via python scripts using the DIRAC-API.
The Auger site is undergoing a major upgrade, which includes the installation of new types of detectors, demanding increased
simulation resources.
The novel detection of the radio component of extensive air showers is the most challenging endeavor, requiring dedicated shower
simulations with very long computation times, not optimized for the grid production.
For data redundancy, the simulations are stored on the Lyon server and the grid Disk Pool Manager and are accessible to the Auger members via iRODS and DIRAC, respectively.
The CERN VM-File System is used for software distribution where, soon, the Auger Offline software will also be made available.
DOI: https://doi.org/10.22323/1.395.0232
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