IceCube-Gen2: the window to the extreme Universe

Aartsen, M. G.; Abbasi, Rasha; Ackermann, M.; Adams, J.; Aguilar, J. A.; Ahlers, M.; Ahrens, M.; Alispach, Cyril Martin; Allison, P.; Amin, Najia Moureen Binte; Andeen, K.; Anderson, Tyler; Ansseau, I.; Anton, G.; Argüelles, C.; Arlen, T. C.; Auffenberg, J.; Axani, Spencer; Bagherpour, H.; Bai, X.; Balagopal, Aswathi; Barbano, Anastasia Maria; Bartos, I.; Bastian, Benjamin; Basu, Vedant; Baum, V.; Baur, S.; Bay, R.; Beatty, J. J.; Becker, Karl‐Heinz; Tjus, Julia Becker; BenZvi, S.; Berley, D.; Bernardini, E.; Besson, D. Z.; Binder, G.; Bindig, D.; Blaufuss, E.; Blot, Summer; Böhm, C.; Böhmer, M.; Böser, S.; Botner, O.; Böttcher, Jakob; Bourbeau, Etienne; Bourbeau, J.; Bradascio, Federica; Braun, J.; Bron, S.; Brostean-Kaiser, Jannes; Burgman, A.; Burley, Ryan; Büscher, J.; Busse, Raffaela; Bustamante, Mauricio; Campana, Michael; Carnie-Bronca, Erin; Carver, T.; Chen, C.; Chen, P.; Cheung, E.; Chirkin, D.; Choi, S.; Clark, Brian; Clark, K.; Classen, L.; Coleman, Alan; Collin, Gabriel; Connolly, A.; Conrad, J. M.; Coppin, Paul; Correa, Pablo; Cowen, D. F.; Cross, R.; Dave, Pranav; Deaconu, C.; Clercq, C. De; DeLaunay, James; Kockere, Simon De; Dembinski, H.-P.; Deoskar, Kunal; Ridder, S. De; Desai, Abhishek; Desiati, P.; Vries, Krijn de; Wasseige, Gwenhaël de; DeWith, Meike; DeYoung, T.; Dharani, Sukeerthi; Dı́az, A.; Díaz–Vélez, Juan Carlos; Dujmović, Hrvoje; Dunkman, M.; DuVernois, Michael; Dvorak, Emily; Ehrhardt, Thomas; Eller, P.; Engel, R.; Evans, John; Evenson, P. A.; Fahey, S.; Farrag, Kareem Ramadan; Fazely, A. R.; Felde, J.; Fienberg, Aaron; Filimonov, K.; Finley, C.; Fischer, Leander; Fox, D. B.; Franckowiak, A.; Friedman, E.; Fritz, A.; Gaisser, T. K.; Gallagher, J.; Ganster, Erik; García-Fernández, Daniel; Garrappa, S.; Gärtner, Andreas; Gerhard, L.; Gernhäeuser, R.; Ghadimi, Ava; Gläser, Christian; Glauch, Theo; Glüsenkamp, T.; Goldschmidt, A.; González, J. G.; Goswami, Sreetama; Grant, D.; Grégoire, T.; Griffith, Z.; Griswold, Spencer; Gündüz, Mehmet; Haack, Christian; Hallgren, A.; Halliday, R.; Halve, L.; Halzen, F.; Hanson, J.; Hanson, K.; Hardin, John; Haugen, J.; Haungs, A.; Hauser, Simon; Hebecker, D.; Heinen, D.; Heix, P.; Helbing, K.; Hellauer, R.; Henningsen, Felix; Hickford, S.; Hignight, J.; Hill, Colton; Hill, G. C.; Hoffman, K. D.; Hoffmann, Benjamin D.; Hoffmann, R.; Hoinka, Tobias; Hokanson-Fasig, B.; Holzapfel, K.; Hoshina, K.; Huang, F.; Huber, Matthías; Huber, Thomas; Huege, T.; Hughes, K.; Hultqvist, K.; Hünnefeld, Mirco; Hussain, Raamis; In, S.; Iovine, N.; Ishihara, A.; Jansson, Matti; Japaridze, G. S.; Jeong, Minjin; Jones, B. J. P.; Jonske, F.; Joppe, R.; Kalekin, O.; Kang, D.; Kang, Woosik; Kang, X.; Kappes, A.; Kappesser, David; Karg, T.; Karl, Martina; Karle, A.; Katori, T.; Katz, U.; Kauer, M.; Keivani, A.; Kellermann, Moritz; Kelley, J. L.; Kheirandish, Ali; Kim, J.; Kin, Ken'ichi; Kintscher, T.; Kiryluk, J.; Kittler, T.; Kleifges, M.; Klein, S. R.; Koirala, R.; Kolanoski, H.; Köpke, L.; Kopper, C.; Kopper, S.; Koskinen, D. J.; Koundal, Paras; Kovacevich, Michael; Kowalski, M.; Krauss, C. B.; Krings, K.; Krückl, G.; Kulacz, N.; Kurahashi, N.; Gualda, Cristina Lagunas; Lahmann, R.; Lanfranchi, J. L.; Larson, M. J.; Latif, Uzair Abdul; Lauber, Frederik Hermann; Lazar, Jeffrey; Leonard, K.; Leszczyńska, Agnieszka; Li, Y.; Liu, Q. R.; Lohfink, Elisa; LoSecco, J. M.; Mariscal, Cristian Jesús Lozano; Lu, Lu; Lucarelli, F.; Ludwig, Andrew; Lünemann, J.; Luszczak, William; Lyu, Y.; Y., W.; Madsen, J.; Maggi, G.; Mahn, Kendall; Makino, Yuya; Mallik, P.; Mancina, Sarah; Mandalia, Shivesh; CMariş, I.; Márka, S.; Márka, Z.; Maruyama, R.; Mase, K.; Maunu, R.; McNally, F.; Meagher, K.; Medina, Andrés; Meier, Maximilian; Meighen-Berger, Stephan; Merz, J.; Meyers, Zachary S.; Micallef, Jessie; Mockler, D.; Momenté, G.; Montaruli, T.; Moore, R. W.; Morse, R.; Moulai, Marjon; Muth, P.; Naab, Richard; Nagai, Ryo; Nam, J. W.; Nauman, U.; Necker, Jannis; Neer, G.; Nelles, A.; Nguyen, Le Viet; Niederhausen, H.; Nisa, Mehr; Nowicki, S. C.; Nygren, D. R.; Oberla, E.; Pollmann, A. Obertacke; Oehler, Marie; Olivas, A.; O’Sullivan, Erin; Pan, Y.; Pandya, Hershal; Pankova, D. V.; Papp, L.; Park, N.; Parker, Grant; Paudel, Ek Narayan; Peiffer, P.; Heros, C. Pérez de los; Petersen, T. C.; Philippen, Saskia; Pieloth, D.; Pieper, Sarah; Pinfold, J. L.; Pizzuto, A.; Plaisier, Ilse; Plum, M.; Popovych, Yuriy; Porcelli, A.; Rodriguez, Maria Prado; Price, P. B.; Przybylski, G. T.; Raab, Christoph; Raissi, Amirreza; Rameez, M.; Rauch, L.; Rawlins, K.; Rea, Immacolata Carmen; Rehman, Abdul; Reimann, R.; Renschler, M.; Renzi, Giovanni; Resconi, E.; Reusch, Simeon; Rhode, W.; Richman, M.; Riedel, Benedikt; Riegel, Michael; Roberts, E. J.; Robertson, Sally; Roellinghoff, Gerrit; Rongen, Martin; Rott, C.; Ruhe, T.; Ryckbosch, D.; Cantu, Devyn Rysewyk; Safa, Ibrahim; Herrera, S. E. Sanchez; Sandrock, Alexander; Sandroos, J.; Sandstrom, P.; Santander, M.; Sarkar, Subir; Satalecka, K.; Scharf, Maximilian Karl; Schaufel, Merlin; Schieler, H.; Schlunder, P.; Schmidt, T.; Schneider, A.; Schneider, Judith; Schröder, Frank G.; Schumacher, Lisa Johanna; Sclafani, S.; Seckel, D.; Seunarine, S.; Shaevitz, M. H.; Sharma, Ankur; Shefali, S.; Silva, M.; Smith, Daniel A.; Smithers, B.; Snihur, R.; Soedingrekso, Jan; Soldin, D.; Söldner-Rembold, S.; Song, M.; Southall, Daniel; Spiczak, G. M.; Spiering, C.; Stachurska, J.; Stamatikos, M.; Stanev, T.; Stein, R.; Stettner, J.; Steuer, A.; Stezelberger, T.; Stokstad, R. G.; Strotjohann, N. L.; Stürwald, Timo; Stuttard, T.; WSullivan, G.; Taboada, I.; Taketa, A.; Tanaka, Hidekazu; Tenholt, F.; Ter–Antonyan, S.; Terliuk, A.; Tilav, S.; Tollefson, K.; Tomankova, L.; Tönnis, Christoph; Torres, Jorge; Toscano, S.; Tosi, D.; Trettin, Alexander; Tselengidou, M.; Tung, Chunfai; Turcati, A.; Turcotte, Roxanne; Turley, C. F.; Twagirayezu, Jean Pierre; Ty, Bunheng; Unger, E.; Elorrieta, M. A. Unland; Vandenbroucke, J.; Eijk, D. van; Eijndhoven, N. van; Vannerom, D.; Santen, J. V.; Veberič, D.; Verpoest, Stef; Vieregg, A. G.; Vraeghe, M.; Walck, C.; Watson, T. B.; Weaver, Ch.; Weindl, A.; Weinstock, Lars Steffen; Weiss, Matthew J.; Weldert, Jan; Welling, Christoph; Wendt, C.; Werthebach, Johannes; Whitehorn, N.; Wiebe, K.; Wiebusch, Christopher; Williams, D. R.; Wissel, S.; Wolf, M.; Wood, T. R.; Woschnagg, K.; Wrede, Gerrit; Wren, Steven; Wulff, Johan; Xu, X. W.; Xu, Y.; Yañez, J. P.; Yoshida, Shigeru; Yuan, Tony; Zhang, Z.; Zierke, S.; Zöcklein, M.

doi:10.1088/1361-6471/abbd48

Cited by 303 publications

(298 citation statements)

References 446 publications

(638 reference statements)

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“…Future work improving measurements of low-and high-energy muons will provide additional input relevant for the understanding of air shower physics. The extension of the Observatory with a larger in-ice detector and new surface detectors [17][18][19] will further allow to expand this work with more complementary measurements.…”

Section: Discussionmentioning

confidence: 99%

Testing Hadronic Interaction Models with Cosmic Ray Measurements at the IceCube Neutrino Observatory

Verpoest¹,

Soldin²,

Ridder³

et al. 2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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The IceCube Neutrino Observatory provides the opportunity to perform unique measurements of cosmic-ray air showers with its combination of a surface array and a deep detector. Electromagnetic particles and low-energy muons (∼GeV) are detected by IceTop, while a bundle of high-energy muons ( 400 GeV) can be measured in coincidence in IceCube. Predictions of air-shower observables based on simulations show a strong dependence on the choice of the high-energy hadronic interaction model. By reconstructing different composition-dependent observables, one can provide strong tests of hadronic interaction models, as these measurements should be consistent with one another. In this work, we present an analysis of air-shower data between 2.5 and 80 PeV, comparing the composition interpretation of measurements of the surface muon density, the slope of the IceTop lateral distribution function, and the energy loss of the muon bundle, using the models Sibyll 2.1, QGSJet-II.04 and EPOS-LHC. We observe inconsistencies in all models under consideration, suggesting they do not give an adequate description of experimental data. The results furthermore imply a significant uncertainty in the determination of the cosmic-ray mass composition through indirect measurements.

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Section: Discussionmentioning

confidence: 99%

Testing Hadronic Interaction Models with Cosmic Ray Measurements at the IceCube Neutrino Observatory

Verpoest¹,

Soldin²,

Ridder³

et al. 2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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“…In the upcoming decade, IceCube Collaboration intends to enhance the current detector to the next-generation instrument, called IceCube-Gen2 [10]. The enhancement will add new detectortypes to the current detector.…”

Section: Based On Graph Neural Networkmentioning

confidence: 99%

Study of mass composition of cosmic rays with IceTop and IceCube

Koundal¹,

Abbasi²,

Ackermann³

et al. 2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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The IceCube Neutrino Observatory is a multi-component detector at the South Pole which detects high-energy particles emerging from astrophysical events. These particles provide us with insights into the fundamental properties and behaviour of their sources. Besides its principal usage and merits in neutrino astronomy, using IceCube in conjunction with its surface array, IceTop, also makes it a unique three-dimensional cosmic-ray detector. This distinctive feature helps facilitate detailed cosmic-ray analysis in the transition region from galactic to extragalactic sources. We will present the progress made on multiple fronts to establish a framework for mass-estimation of primary cosmic rays. The first technique relies on a likelihood-based analysis of the surface signal distribution and improves upon the standard reconstruction technique. The second uses advanced methods in graph neural networks to use the full in-ice shower footprint, in addition to global shower-footprint features from IceTop. A comparison between the two methods for composition analysis as well as a possible extension of the analysis techniques for sub-PeV cosmic-ray airshowers will also be discussed.

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“…In this work [7] we have used the future neutrino radio telescopes RNO-G [8], IceCube-Gen2 radio array [9,10] and GRAND [11] in order to explore the parameter space of heavy dark matter particles with masses in the range [10 7 − 10 15 ] GeV, focusing on the decay rather than in the annihilation due to the higher produced neutrino fluxes. We will assume that the neutrino telescopes will measure only the cosmogenic neutrino contribution or the newborn pulsars one and extract in this way the limits that we could place on the lifetime of the dark matter particles using the projected sensitivities of the aforementioned telescopes.…”

Section: Introductionmentioning

confidence: 99%

Testing the stability of heavy dark matter with up-coming radio neutrino telescopes

Hajjar¹

2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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Astrophysical neutrinos with energies higher than > 10 PeV have not been measured yet, therefore, we do not know what kind of sources are contributing to this high energy neutrino flux. Concretely, we are interested in testing the hypothesis in which we have a hidden contribution coming from the decay of heavy dark matter particles. The first neutrino radio telescopes will be constructed during the following decade, having as a principal goal the detection of the cosmogenic neutrinos, and being able to disentangle the principal source contributing at these high energies for the astrophysical neutrino flux. In this work we study the projected sensitivity of up-coming neutrino radio telescopes, such as RNO-G, GRAND and IceCube-Gen2 radio array, to decaying dark matter scenarios. We perform a forecast analysis in order to place conservative constraints on the lifetime of dark matter within the range DM = [10 7 − 10 15 ] GeV after assuming the dominant astrophysical neutrino source, the one that will act as our background for the hidden dark matter signal. These forecasted limits open a new parameter space for some decaying channels, and complement the limits obtained for the channel due to its multi-messenger agreement.

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IceCube-Gen2: the window to the extreme Universe

Cited by 303 publications

References 446 publications

Testing Hadronic Interaction Models with Cosmic Ray Measurements at the IceCube Neutrino Observatory

Testing Hadronic Interaction Models with Cosmic Ray Measurements at the IceCube Neutrino Observatory

Study of mass composition of cosmic rays with IceTop and IceCube

Testing the stability of heavy dark matter with up-coming radio neutrino telescopes

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