Advanced search
1 file | 914.37 KB

Measurement of the νμ energy spectrum with IceCube-79

Author
Organization
Abstract
IceCube is a neutrino observatory deployed in the glacial ice at the geographic South Pole. The nu(mu) energy unfolding described in this paper is based on data taken with IceCube in its 79-string configuration. A sample of muon neutrino charged-current interactions with a purity of 99.5% was selected by means of amultivariate classification process based on machine learning. The subsequent unfolding was performed using the software TRUEE. The resulting spectrum covers an E-nu-range of more than four orders of magnitude from 125 GeV to 3.2 PeV. Compared to the Honda atmospheric neutrino flux model, the energy spectrum shows an excess of more than 1.9 sigma in four adjacent bins for neutrino energies E-nu >= 177.8 TeV. The obtained spectrum is fully compatible with previous measurements of the atmospheric neutrino flux and recent IceCube measurements of a flux of high-energy astrophysical neutrinos.
Keywords
NEUTRINO TELESCOPES, DETECTOR, ASTROPHYSICS, AMANDA, SYSTEM, FLUX

Downloads

  • 027.pdf
    • full text
    • |
    • open access
    • |
    • PDF
    • |
    • 914.37 KB

Citation

Please use this url to cite or link to this publication:

Chicago
Aartsen, MG, M Ackermann, J Adams, JA Aguilar, M Ahlers, M Ahrens, I Al Samarai, et al. 2017. “Measurement of the Νμ Energy Spectrum with IceCube-79.” European Physical Journal C 77 (10).
APA
Aartsen, M., Ackermann, M., Adams, J., Aguilar, J., Ahlers, M., Ahrens, M., Al Samarai, I., et al. (2017). Measurement of the νμ energy spectrum with IceCube-79. EUROPEAN PHYSICAL JOURNAL C, 77(10).
Vancouver
1.
Aartsen M, Ackermann M, Adams J, Aguilar J, Ahlers M, Ahrens M, et al. Measurement of the νμ energy spectrum with IceCube-79. EUROPEAN PHYSICAL JOURNAL C. 2017;77(10).
MLA
Aartsen, MG et al. “Measurement of the Νμ Energy Spectrum with IceCube-79.” EUROPEAN PHYSICAL JOURNAL C 77.10 (2017): n. pag. Print.
@article{8565603,
  abstract     = {IceCube is a neutrino observatory deployed in the glacial ice at the geographic South Pole. The nu(mu) energy unfolding described in this paper is based on data taken with IceCube in its 79-string configuration. A sample of muon neutrino charged-current interactions with a purity of 99.5\% was selected by means of amultivariate classification process based on machine learning. The subsequent unfolding was performed using the software TRUEE. The resulting spectrum covers an E-nu-range of more than four orders of magnitude from 125 GeV to 3.2 PeV. Compared to the Honda atmospheric neutrino flux model, the energy spectrum shows an excess of more than 1.9 sigma in four adjacent bins for neutrino energies E-nu {\textrangle}= 177.8 TeV. The obtained spectrum is fully compatible with previous measurements of the atmospheric neutrino flux and recent IceCube measurements of a flux of high-energy astrophysical neutrinos.},
  articleno    = {692},
  author       = {Aartsen, MG and Ackermann, M and Adams, J and Aguilar, JA and Ahlers, M and Ahrens, M and Al Samarai, I and Altmann, D and Andeen, K and Anderson, T and Ansseau, I and Anton, G and Archinger, M and Arguelles, C and Auffenberg, J and Axani, S and Bagherpour, H and Bai, X and Barwick, SW and Baum, V and Bay, R and Beatty, JJ and Becker Tjus, J and Becker, K-H and BenZvi, S and Berley, D and Bernardini, E and Besson, DZ and Binder, G and Bindig, D and Blaufuss, E and Blot, S and Bohm, C and Boerner, M and Bos, F and Bose, D and Boeser, S and Botner, O and Bradascio, F and Braun, J and Brayeur, L and Bretz, H-P and Bron, S and Burgman, A and Carver, T and Casier, M and Cheung, E and Chirkin, D and Christov, A and Clark, K and Classen, L and Coenders, S and Collin, GH and Conrad, JM and Cowen, DF and Cross, R and Day, M and de Andre, JPAM and De Clercq, C and del Pino Rosendo, E and Dembinski, H and De Ridder, Sam and Desiati, P and de Vries, KD and de Wasseige, G and de With, M and DeYoung, T and Diaz-Velez, JC and di Lorenzo, V and Dujmovic, H and Dumm, JP and Dunkman, M and Eberhardt, B and Ehrhardt, T and Eichmann, B and Eller, P and Euler, S and Evenson, PA and Fahey, S and Fazely, AR and Feintzeig, J and Felde, J and Filimonov, K and Finley, C and Flis, S and Foesig, C-C and Franckowiak, A and Friedman, E and Fuchs, T and Gaisser, TK and Gallagher, J and Gerhardt, L and Ghorbani, K and Giang, W and Gladstone, L and Glauch, T and Gluesenkamp, T and Goldschmidt, A and Gonzalez, JG and Grant, D and Griffith, Z and Haack, C and Hallgren, A and Halzen, F and Hansen, E and Hansmann, T and Hanson, K and Hebecker, D and Heereman, D and Helbing, K and Hellauer, R and Hickford, S and Hignight, J and Hill, GC and Hoffman, KD and Hoffmann, R and Hoshina, K and Huang, F and Huber, M and Hultqvist, K and In, S and Ishihara, A and Jacobi, E and Japaridze, GS and Jeong, M and Jero, K and Jones, BJP and Kang, W and Kappes, A and Karg, T and Karle, A and Katz, U and Kauer, M and Keivani, A and Kelley, JL and Kheirandish, A and Kim, J and Kim, M and Kintscher, T and Kiryluk, J and Kittler, T and Klein, SR and Kohnen, G and Koirala, R and Kolanoski, H and Konietz, R and Koepke, L and Kopper, C and Kopper, S and Koskinen, DJ and Kowalski, M and Krings, K and Kroll, M and Krueckl, G and Krueger, C and Kunnen, J and Kunwar, S and Kurahashi, N and Kuwabara, T and Kyriacou, A and Labare, Mathieu and Lanfranchi, JL and Larson, MJ and Lauber, F and Lennarz, D and Lesiak-Bzdak, M and Leuermann, M and Lu, L and Lunemann, J and Larson, MJ and Maggi, G and Mahn, KBM and Mancina, S and Maruyama, R and Mase, K and Maunu, R and McNally, F and Meagher, K and Medici, M and Meier, M and Menne, T and Merino, G and Meures, T and Miarecki, S and Micallef, J and Momente, G and Montaruli, T and Moulai, M and Nahnhauer, R and Naumann, U and Neer, G and Niederhausen, H and Nowicki, SC and Nygren, DR and Obertacke Pollmann, A and Olivas, A and O'Murchadha, A and Palczewski, T and Pandya, H and Pankova, DV and Peiffer, P and Penek, O and Pepper, JA and Pepper, JA and Perez De Los Heros, C and Pieloth, D and Pinat, E and Price, PB and Przybylski, GT and Quinnan, M and Raab, C and Raedel, L and Rameez, M and Rawlins, K and Reimann, R and Relethford, B and Relich, M and Resconi, E and Rhode, W and Richman, M and Riedel, B and Robertson, S and Rongen, M and Rott, C and Ruhe, T and Ryckbosch, Dirk and Rysewyk, D and Sabbatini, L and Sanchez Herrera, SE and Sandrock, A and Sandroos, J and Sarkar, S and Satalecka, K and Schlunder, P and Schmidt, T and Schoenen, S and Schoeneberg, S and Schumacher, L and Seckel, D and Seunarine, S and Soldin, D and Song, M and Spiczak, GM and Spiering, C and Stachurska, J and Stanev, T and Stasik, A and Stettner, J and Steuer, A and Stezelberger, T and Stokstad, RG and Stossl, A and Strom, R and Strotjohann, NL and Sullivan, GW and Sutherland, M and Taavola, H and Taboada, I and Tatar, J and Tenholt, F and Ter-Antonyan, S and Terliuk, A and Tesic, G and Tilav, S and Toale, PA and Tobin, MN and Toscano, S and Tosi, D and Tselengidou, M and Tung, CF and Turcati, A and Unger, E and Usner, M and Vandenbroucke, J and van Eijndhoven, N and Vanheule, Sander and van Rossem, M and van Santen, J and Vehring, M and Voge, M and Vogel, E and Vraeghe, Matthias and Walck, C and Wallace, A and Wallraff, M and Wandkowsky, N and Waza, A and Weaver, Ch and Weiss, MJ and Wendt, C and Westerhoff, S and Whelan, BJ and Wickmann, S and Wiebe, K and Wiebusch, CH and Wille, L and Williams, DR and Wills, L and Wolf, M and Wood, TR and Woolsey, E and Woschnagg, K and Xu, DL and Xu, XW and Xu, Y and Yanez, JP and Yodh, G and Yoshida, S and Zoll, M},
  issn         = {1434-6044},
  journal      = {EUROPEAN PHYSICAL JOURNAL C},
  language     = {eng},
  number       = {10},
  pages        = {12},
  title        = {Measurement of the \ensuremath{\nu}\ensuremath{\mu} energy spectrum with IceCube-79},
  url          = {http://dx.doi.org/10.1140/epjc/s10052-017-5261-3},
  volume       = {77},
  year         = {2017},
}

Altmetric
View in Altmetric
Web of Science
Times cited: