The detection of MeV-GeV neutrinos from astronomical sources is a long-lasting challenge for neutrino experiments. The low flux predicted for transient sources, such as solar flares, and their low-energy signature, requires a detector with both a large instrumented volume as well as a high density of photomultiplier tubes (PMTs). We discuss how KM3NeT can play a key role in the search for these neutrinos. KM3NeT is a Cherenkov neutrino telescope currently under deployment, located at the bottom of the Mediterranean Sea. It consists of two arrays of Digital Optical Modules (DOMs): KM3NeT/ORCA and KM3NeT/ARCA, which are optimised for the detection of GeV neutrinos for oscillation studies, and higher-energy astronomical neutrinos respectively. We exploit the multi-PMT configuration of KM3NeT’s DOMs to develop the techniques that allow the disentangling of the MeV-GeV neutrino signature from the atmospheric and environmental background. Comparing data with neutrino simulations we identify the variables with discriminating power, and by applying hard cuts we are able to reject a large fraction of background. We present a graph neural network approach to classify signal from background. To further improve the sensitivities compared to previous studies, we will make use of the Hierarchical Graph Pooling with Structure Learning algorithm and will use graph-structured data to reproduce the hit geometry on the DOM. This will allow for stronger constraints on the hits and reduce the fraction of background that survives the selection.
Improving the sensitivity of KM3NeT to MeV-GeV neutrinos from solar flares / Mauro, J.; De Wasseige, G.; Aiello, S.; Albert, A.; Alves Garre, S.; Aly, Z.; Ambrosone, A.; Ameli, F.; Andre, M.; Androutsou, E.; Anguita, M.; Aphecetche, L.; Ardid, M.; Ardid, S.; Atmani, H.; Aublin, J.; Bailly-Salins, L.; Bardacova, Z.; Baret, B.; Bariego-Quintana, A.; Basegmez Du Pree, S.; Becherini, Y.; Bendahman, M.; Benfenati, F.; Benhassi, M.; Benoit, D. M.; Berbee, E.; Bertin, V.; Biagi, S.; Boettcher, M.; Bonanno, D.; Boumaaza, J.; Bouta, M.; Bouwhuis, M.; Bozza, C.; Bozza, R. M.; Branzas, H.; Bretaudeau, F.; Bruijn, R.; Brunner, J.; Bruno, R.; Buis, E.; Buompane, R.; Busto, J.; Caiffi, B.; Calvo, D.; Campion, S.; Capone, A.; Carenini, F.; Carretero, V.; Cartraud, T.; Castaldi, P.; Cecchini, V.; Celli, S.; Cerisy, L.; Chabab, M.; Chadolias, M.; Chen, A.; Cherubini, S.; Chiarusi, T.; Circella, M.; Cocimano, R.; Coelho, J. A. B.; Coleiro, A.; Coniglione, R.; Coyle, P.; Creusot, A.; Cruz, A.; Cuttone, G.; Dallier, R.; Darras, Y.; De Benedittis, A.; De Martino, B.; De Wasseige, G.; Decoene, V.; Del Burgo, R.; Di Cerbo, U. M.; Di Mauro, L. S.; Di Palma, I.; Diaz, A. F.; Diaz, C.; Diego-Tortosa, D.; Distefano, C.; Domi, A.; Donzaud, C.; Dornic, D.; Dorr, M.; Drakopoulou, E.; Drouhin, D.; Dvornicky, R.; Eberl, T.; Eckerova, E.; Eddymaoui, A.; Van Eeden, T.; Eff, M.; Van Eijk, D.; El Bojaddaini, I.; El Hedri, S.; Enzenhofer, A.; De Favereau, J.; Ferrara, G.; Filipovic, M. D.; Filippini, F.; Franciotti, D.; Fusco, L. A.; Gabriel, J.; Gagliardini, S.; Gal, T.; Garcia Mendez, J.; Garcia Soto, A.; Gatius Oliver, C.; Geisselbrecht, N.; Ghaddari, H.; Gialanella, L.; Gibson, B. K.; Giorgio, E.; Goos, I.; Goupilliere, D.; Gozzini, S. R.; Gracia, R.; Graf, K.; Guidi, C.; Guillon, B.; Gutierrez, M.; Van Haren, H.; Heijboer, A.; Hekalo, A.; Hennig, L.; Hernandez-Rey, J. J.; Huang, F.; Idrissi Ibnsalih, W.; Illuminati, G.; James, C. W.; De Jong, M.; De Jong, P.; Jung, B. J.; Kalaczynski, P.; Kalekin, O.; Katz, U. F.; Khan Chowdhury, N. R.; Khatun, A.; Kistauri, G.; Kopper, C.; Kouchner, A.; Kulikovskiy, V.; Kvatadze, R.; Labalme, M.; Lahmann, R.; Lamoureux, M.; Larosa, G.; Lastoria, C.; Lazo, A.; Le Stum, S.; Lehaut, G.; Leonora, E.; Lessing, N.; Levi, G.; Lindsey Clark, M.; Longhitano, F.; Majumdar, J.; Malerba, L.; Mamedov, F.; Manczak, J.; Manfreda, A.; Marconi, M.; Margiotta, A.; Marinelli, A.; Markou, C.; Martin, L.; Martinez-Mora, J. A.; Marzaioli, F.; Mastrodicasa, M.; Mastroianni, S.; Mauro, J.; Micciche, S.; Miele, G.; Migliozzi, P.; Migneco, E.; Mitsou, M. L.; Mollo, C. M.; Morales-Gallegos, L.; Morley-Wong, C.; Moussa, A.; Mozun Mateo, I.; Muller, R.; Musone, M. R.; Musumeci, M.; Nauta, L.; Navas, S.; Nayerhoda, A.; Nicolau, C. A.; Nkosi, B.; Fearraigh, B. O.; Oliviero, V.; Orlando, A.; Oukacha, E.; Paesani, D.; Palacios Gonzalez, J.; Papalashvili, G.; Parisi, V.; Pastor Gomez, E. J.; Paun, A. M.; Pavalas, G. E.; Pena Martinez, S.; Perrin-Terrin, M.; Perronnel, J.; Pestel, V.; Pestes, R.; Piattelli, P.; Poire, C.; Popa, V.; Pradier, T.; Pulvirenti, S.; Quemener, G.; Quiroz, C.; Rahaman, U.; Randazzo, N.; Randriatoamanana, R.; Razzaque, S.; Rea, I. C.; Real, D.; Reck, S.; Riccobene, G.; Robinson, J.; Romanov, A.; Saina, A.; Salesa Greus, F.; Samtleben, D. F. E.; Sanchez Losa, A.; Sanfilippo, S.; Sanguineti, M.; Santonastaso, C.; Santonocito, D.; Sapienza, P.; Schnabel, J.; Schumann, J.; Schutte, H. M.; Seneca, J.; Sennan, N.; Setter, B.; Sgura, I.; Shanidze, R.; Shitov, Y.; Simkovic, F.; Simonelli, A.; Sinopoulou, A.; Smirnov, M. V.; Spisso, B.; Spurio, M.; Stavropoulos, D.; Stekl, I.; Taiuti, M.; Tayalati, Y.; Tedjditi, H.; Thiersen, H.; Tosta E Melo, I.; Trocme, B.; Tsourapis, V.; Tzamariudaki, E.; Vacheret, A.; Valsecchi, V.; Van Elewyck, V.; Vannoye, G.; Vasileiadis, G.; Vazquez De Sola, F.; Verilhac, C.; Veutro, A.; Viola, S.; Vivolo, D.; Wilms, J.; De Wolf, E.; Yepes-Ramirez, H.; Zarpapis, G.; Zavatarelli, S.; Zegarelli, A.; Zito, D.; Zornoza, J. D.; Zuniga, J.; Zywucka, N.. - In: POS PROCEEDINGS OF SCIENCE. - ISSN 1824-8039. - 444:(2024), pp. 1-10. ( 38th International Cosmic Ray Conference, ICRC 2023 Nagoya, Japan ) [10.22323/1.444.1294].
Improving the sensitivity of KM3NeT to MeV-GeV neutrinos from solar flares
Ameli F.;Campion S.;Capone A.;Celli S.;Di Palma I.;Gagliardini S.;Mastrodicasa M.;Nicolau C. A.;Veutro A.;Zegarelli A.;
2024
Abstract
The detection of MeV-GeV neutrinos from astronomical sources is a long-lasting challenge for neutrino experiments. The low flux predicted for transient sources, such as solar flares, and their low-energy signature, requires a detector with both a large instrumented volume as well as a high density of photomultiplier tubes (PMTs). We discuss how KM3NeT can play a key role in the search for these neutrinos. KM3NeT is a Cherenkov neutrino telescope currently under deployment, located at the bottom of the Mediterranean Sea. It consists of two arrays of Digital Optical Modules (DOMs): KM3NeT/ORCA and KM3NeT/ARCA, which are optimised for the detection of GeV neutrinos for oscillation studies, and higher-energy astronomical neutrinos respectively. We exploit the multi-PMT configuration of KM3NeT’s DOMs to develop the techniques that allow the disentangling of the MeV-GeV neutrino signature from the atmospheric and environmental background. Comparing data with neutrino simulations we identify the variables with discriminating power, and by applying hard cuts we are able to reject a large fraction of background. We present a graph neural network approach to classify signal from background. To further improve the sensitivities compared to previous studies, we will make use of the Hierarchical Graph Pooling with Structure Learning algorithm and will use graph-structured data to reproduce the hit geometry on the DOM. This will allow for stronger constraints on the hits and reduce the fraction of background that survives the selection.| File | Dimensione | Formato | |
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