Combined search for neutrinos from dark matter self-annihilation in the Galactic Center with ANTARES and IceCube

Albert, A.; André, M.; Anghinolfi, M.; Ardid, M.; Aubert, J.J.; Aublin, J.; Baret, B.; Basa, S.; Belhorma, B.; Bertín, V.; Biagi, S.; Bissinger, M.; Boumaaza, J.; Bouta, M.; Bouwhuis, M. C.; Brânzaş, H.; Bruijn, R.; Brünner, J.; Busto, J.; Capone, A.; Caramete, L.; Carr, J.; Celli, S.; Chabab, M.; Chau, Thien Nhan; Moursli, R. Cherkaoui El; Chiarusi, T.; Circella, M.; Coleiro, A.; Colomer, M.; Coniglione, R.; Coyle, P.; Creusot, A.; Deschamps, A.; Distefano, C.; Palma, I. Di; Domi, Alba; Donzaud, C.; Dornic, D.; Drouhin, D.; Eberl, T.; Khayati, N. El; Enzenhöfer, A.; Ettahiri, A.; Fermani, P.; Ferrara, G.; Filippini, F.; Fusco, L.; Gay, P.; Glotin, Hervé; Gozzini, R.; Ruiz, R. Gracia; Graf, Κ.; Guidi, C.; Hallmann, S.; Haren, Hans van; Heijboer, A.; Hello, Y.; Hernández-Rey, J. J.; Hößl, J.; Hofestädt, J.; Huang, Feng; Illuminati, G.; James, C. W.; Jong, M. de; Jong, P. de; Jongen, M.; Kadler, M.; Kalekin, O.; Katz, U.; Khan-Chowdhury, N. R.; Kouchner, A.; Kreykenbohm, I.; Kulikovskiy, V.; Lahmann, R.; Breton, R. Le; Lefèvre, D.; Leonora, E.; Levi, G.; Lincetto, Massimiliano; Lopez-Coto, D.; Loucatos, S.; Maggi, G.; Mańczak, J.; Marcelin, M.; Margiotta, A.; Marinelli, A.; Martínez-Mora, J. A.; Mele, R.; Melis, K.; Migliozzi, P.; Möser, Michael; Moussa, A.; Müller, R.; Nauta, L.; Navas, S. Sánchez; Nezri, E.; Nielsen, C.; Núñez-Castiñeyra, A.; O’Fearraigh, B.; Organokov, M.; Păvălaş, G. E.; Pellegrino, C.; Perrin-Terrin, M.; Piattelli, P.; Poirè, C.; Popa, V.; Pradier, T.; Randazzo, N.; Reck, S.; Riccobene, G.; Sánchez-Losa, A.; Samtleben, D. F. E.; Sanguineti, M.; Sapienza, P.; Schüßler, F.; Spurio, M.; Stolarczyk, Th.; Strandberg, B.; Taiuti, M.; Tayalati, Y.; Thakore, T.; Tingay, S. J.; Trovato, A.; Vallage, B.; Elewyck, V. Van; Versari, F.; Viola, S.; Vivolo, D.; Wilms, J.; Zaborov, D.; Zegarelli, A.; Zornoza, J. D.; Zúñiga, J.; Aartsen, M. G.; Ackermann, M.; Adams, J. H.; Aguilar, J. A.; Ahlers, M.; Ahrens, M.; Alispach, Cyril Martin; Andeen, K.; Anderson, W. G.; Ansseau, I.; Anton, G.; Argüelles, C.; Auffenberg, J.; Axani, Spencer; Bagherpour, H.; Bai, X.; Balagopal, Aswathi; Barbano, Anastasia Maria; Barwick, S. W.; Bastian, Benjamin; Baum, V.; Baur, S.; Bay, R.; Beatty, J. J.; Becker, Karl‐Heinz; Tjus, Julia Becker; BenZvi, S.; Berley, D.; Bernardini, E.; Besson, D.; Binder, G.; Bindig, D.; Blaufuss, E.; Blot, Summer; Böhm, C.; Böser, S.; Botner, O.; Böttcher, Jakob; Bourbeau, Etienne; Bourbeau, J.; Bradascio, Federica; Braun, J.; Bron, S.; Brostean-Kaiser, Jannes; Burgman, A.; Büscher, J.; Busse, Raffaela; Carver, T.; Chen, C.; Cheung, E.; Chirkin, D.; Choi, S.; Clark, Brian; Clark, K.; Classen, L.; Coleman, Alan; Collin, Gabriel; Conrad, J.; Coppin, Paul; Correa, Pablo; Cowen, D. F.; Cross, R.; Dave, Pranav; Clercq, C. De; DeLaunay, James; Dembinski, H.-P.; Deoskar, Kunal; Ridder, S. De; Desiati, P.; Vries, Krijn de; Wasseige, Gwenhaël de; With, M. de; DeYoung, T.; Dı́az, A.; Díaz–Vélez, Juan Carlos; Dujmović, Hrvoje; Dunkman, M.; Dvorak, Emily; Eberhardt, B.; Ehrhardt, Thomas; Eller, P.; Engel, R.; Evenson, P. A.; Fahey, S.; Fazely, A. R.; Felde, J.; Filimonov, K.; Finley, C.; Fox, D. B.; Franckowiak, A.; Friedman, E.; Fritz, A.; Gaisser, T. K.; Gallagher, J.; Ganster, Erik; Garrappa, S.; Gerhardt, L.; Ghorbani, K.; Glauch, Theo; Glüsenkamp, T.; Goldschmidt, A.; González, J. G.; Grant, D.; Grégoire, T.; Griffith, Z.; Griswold, Spencer; Günder, M.; Gündüz, Mehmet; Haack, Christian; Hallgren, A.; Halliday, R.; Halve, L.; Halzen, F.; Hanson, K.; Haungs, A.; Hebecker, D.; Heereman, D.; Heix, P.; Helbing, K.; Hellauer, R.; Henningsen, Felix; Hickford, S.; Hignight, J.; Hill, G. C.; Hoffman, K. 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G.; Stößl, A.; Strotjohann, N. L.; Stürwald, Timo; Stuttard, Thomas; Sullivan, G. W.; Taboada, I.; Tenholt, F.; Ter–Antonyan, S.; Terliuk, A.; Tilav, S.; Tollefson, K.; Tomankova, L.; Tönnis, Christoph; Toscano, S.; Tosi, D.; Trettin, Alexander; Tselengidou, M.; Tung, Chun Fai; Turcati, A.; Turcotte, Roxanne; Turley, C. F.; Ty, Bunheng; Unger, E.; Elorrieta, M. A. Unland; Usner, M.; Vandenbroucke, J.; Driessche, W. Van; Eijk, D. van; Eijndhoven, N. van; Santen, J. V.; Verpoest, Stef; Vraeghe, M.; Walck, C.; Wallace, A.; Wallraff, M.; Wandkowsky, N.; Watson, T. B.; Weaver, Ch.; Weindl, A.; Weiss, Matthew J.; Weldert, Jan; Wendt, C.; Werthebach, Johannes; Whelan, B. J.; Whitehorn, N.; Wiebe, K.; Wiebusch, C. H.; Wille, L.; Williams, D. R.; Wills, L.; Wolf, M.; Wood, J.; Wood, T. R.; Woschnagg, K.; Wrede, Gerrit; Xu, D. L.; Xu, X. W.; Xu, Yunlin; Yañez, J. P.; Yodh, G.; Yoshida, Shigeru; Yuan, Tianlu; Zöcklein, M.

doi:10.1103/physrevd.102.082002

Cited by 53 publications

(64 citation statements)

References 42 publications

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“…Independent of UV motivations, there is a clear reason to consider searching for such DM: the robust experimental program to probe astrophysical messengers at higher energies. Many instruments can probe heavy DM, including HAWC [32], IceCube [5,[33][34][35][36][37][38], ANTARES [39,40], Pierre Auger Observatory [41][42][43][44], Telescope Array [45,46], and in the future CTA [47,48], LHAASO [49,50], IceCube-Gen2 [51], and KM3NET [52,53]. Taken together, these experiments demonstrate that in the coming years we will continue to probe the universe at higher energies and to greater sensitivities.…”

Section: Introductionmentioning

confidence: 97%

Dark matter spectra from the electroweak to the Planck scale

Bauer

Rodd

Webber

2021

J. High Energ. Phys.

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We compute the decay spectrum for dark matter (DM) with masses above the scale of electroweak symmetry breaking, all the way to the Planck scale. For an arbitrary hard process involving a decay to the unbroken standard model, we determine the prompt distribution of stable states including photons, neutrinos, positrons, and antiprotons. These spectra are a crucial ingredient in the search for DM via indirect detection at the highest energies as being probed in current and upcoming experiments including IceCube, HAWC, CTA, and LHAASO. Our approach improves considerably on existing methods, for instance, we include all relevant electroweak interactions.

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Section: Introductionmentioning

confidence: 97%

Dark matter spectra from the electroweak to the Planck scale

Bauer

Rodd

Webber

2021

J. High Energ. Phys.

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“…Neutral particle (neutrino and gamma) searches are typically done by searching for signals from sources with higher DM concentrations [84], while cosmic ray antiparticles can also provide insight into dark matter [85]. Sources that would be expected to provide a strong DM signal include the galactic DM halo [86], the Galactic Centre [87], dwarf spheroidal galaxies [88], the CMB as well as signals from…”

Section: Indirect Detectionmentioning

confidence: 99%

“…(4.2)This neutrino flux depends on the annihilation cross section σ A v , the DM mass m χ , the final state energy spectrum dNν dEν , as well as the DM density distribution along the l.o.s, ρ χ . In the case of IceCube, a DM annihilation search has been performed for the Galactic Centre, where limits down to 7.44 × 10 −24 cm 3 s −1 were found for a 200 GeV DM particle annihilating through the τ + τ − channel[87,93,94]. Better limits can also be achieved with gamma ray studies which have placed upper limits on the thermally averaged cross section at σ A v 10 −26 cm 3 s −1 for a 200 GeV dark matter through annihilation to τ + τ −[84].…”

mentioning

confidence: 99%

Dark matter neutrino scattering in the galactic centre with IceCube

McMullen¹,

Vincent²,

Argüelles³

et al. 2021

J. Inst.

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While there is evidence for the existence of dark matter, its properties have yet to be discovered. Simultaneously, the nature of high-energy astrophysical neutrinos detected by IceCube remains unresolved. If dark matter and neutrinos are coupled to each other, they could exhibit a non-zero elastic scattering cross section. Such an interaction between an isotropic extragalactic neutrino flux and dark matter would be concentrated in the Galactic Centre, where the dark matter column density is the greatest. This scattering would attenuate the flux of high-energy neutrinos, which could be observed in the IceCube South Pole Neutrino Observatory. In this thesis, an unbinned likelihood analysis is performed to set sensitivities for the seven year medium energy starting event cascades dataset for a signal considering possible dark matterneutrino interaction scenarios. This signal would be observed as a suppression of the high-energy astrophysical neutrino flux in the direction of the Galactic Centre. It is shown that IceCube can set constraints on possible dark matter-neutrino interactions that are complementary to constraints set by large scale structure surveys and the cosmic microwave background. i I would like to thank my supervisor Aaron Vincent at Queen's and co-supervisor Carlos Argüelles at Harvard for their support and guidance during the course of this thesis. I have been extremely lucky to have great supervisors who patiently answer all my questions and provide invaluable advice. I would also like to thank Austin Schneider for his excellent insight with this analysis. I would like to acknowledge the support of NSERC, the IceCube collaboration, the Frontenac Cluster, and the Canadian Armed Forces in making this thesis possible. I would also like to thank all my family and friends for their support during this degree. I would especially like to thank Eric and Mikayla McMullen for editing this thesis and Simran Nerval for providing feedback for my thesis presentation. I would also like to thank the members of my thesis committee, Joe Bramante and Nahee Park for their comments and discussion during the thesis defence.

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“…The currently widely used fluxes in neutrino experiments such as ANTARES, IceCube, Super-Kamiokande (See e.g. [1][2][3][4]) are from DarkSUSY [5], PPPC [6,7], WimpSim [8,9], and direct PYTHIA [10] generation. There similarities and differences of different computations will not be discussed in this proceeding.…”

Section: Introductionmentioning

confidence: 99%

χaroν: a tool for neutrino flux generation from WIMPs

Liu¹,

Lazar²,

Argüelles³

et al. 2021

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

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Indirect searches for signatures of corpuscular dark matter have been performed using all cosmic messengers: gamma rays, cosmic rays, and neutrinos. The search for dark matter with neutrinos is important since they are the only courier that can reach detectors from dark matter processes in dense environments, such as the core of the Sun or Earth, or the edge of the observable Universe. One thing essential to experiments is the prediction of the neutrino signature in the detector. I will introduce aro , a software that bridges the dark sector and Standard Model by predicting neutrino fluxes from different celestial dark matter agglomerations in diverse scenarios. This package includes an updated computation of neutrino production and propagation to the detector.

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Combined search for neutrinos from dark matter self-annihilation in the Galactic Center with ANTARES and IceCube

Cited by 53 publications

References 42 publications

Dark matter spectra from the electroweak to the Planck scale

Dark matter spectra from the electroweak to the Planck scale

Dark matter neutrino scattering in the galactic centre with IceCube

χaroν: a tool for neutrino flux generation from WIMPs

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