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Search for sub-TeV Neutrino Emission from Novae with IceCube-DeepCore

Authors :
Abbasi, R.
Ackermann, M.
Adams, J.
Aggarwal, N.
Aguilar, J. A.
Ahlers, M.
Alameddine, J. M.
Alves Jr., A. A.
Amin, N. M.
Andeen, K.
Anderson, T.
Anton, G.
Argüelles, C.
Ashida, Y.
Athanasiadou, S.
Axani, S. N.
Bai, X.
V., A. Balagopal
Baricevic, M.
Barwick, S. W.
Basu, V.
Bay, R.
Beatty, J. J.
Becker, K. -H.
Tjus, J. Becker
Beise, J.
Bellenghi, C.
BenZvi, S.
Berley, D.
Bernardini, E.
Besson, D. Z.
Binder, G.
Bindig, D.
Blaufuss, E.
Blot, S.
Bontempo, F.
Book, J. Y.
Borowka, J.
Meneguolo, C. Boscolo
Böser, S.
Botner, O.
Böttcher, J.
Bourbeau, E.
Braun, J.
Brinson, B.
Brostean-Kaiser, J.
Burley, R. T.
Busse, R. S.
Campana, M. A.
Carnie-Bronca, E. G.
Chen, C.
Chen, Z.
Chirkin, D.
Choi, S.
Clark, B. A.
Classen, L.
Coleman, A.
Collin, G. H.
Connolly, A.
Conrad, J. M.
Coppin, P.
Correa, P.
Countryman, S.
Cowen, D. F.
Dappen, C.
Dave, P.
De Clercq, C.
DeLaunay, J. J.
López, D. Delgado
Dembinski, H.
Deoskar, K.
Desai, A.
Desiati, P.
de Vries, K. D.
de Wasseige, G.
DeYoung, T.
Diaz, A.
Diaz-Vélez, J. C.
Dittmer, M.
Dujmovic, H.
DuVernois, M. A.
Ehrhardt, T.
Eller, P.
Engel, R.
Erpenbeck, H.
Evans, J.
Evenson, P. A.
Fan, K. L.
Fazely, A. R.
Fedynitch, A.
Feigl, N.
Fiedlschuster, S.
Fienberg, A. T.
Finley, C.
Fischer, L.
Fox, D.
Franckowiak, A.
Friedman, E.
Fritz, A.
Fürst, P.
Gaisser, T. K.
Gallagher, J.
Ganster, E.
Garcia, A.
Garrappa, S.
Gerhardt, L.
Ghadimi, A.
Glaser, C.
Glauch, T.
Glüsenkamp, T.
Goehlke, N.
Gonzalez, J. G.
Goswami, S.
Grant, D.
Gray, S. J.
Grégoire, T.
Griffin, S.
Griswold, S.
Günther, C.
Gutjahr, P.
Haack, C.
Hallgren, A.
Halliday, R.
Halve, L.
Halzen, F.
Hamdaoui, H.
Minh, M. Ha
Hanson, K.
Hardin, J.
Harnisch, A. A.
Hatch, P.
Haungs, A.
Helbing, K.
Hellrung, J.
Henningsen, F.
Heuermann, L.
Hickford, S.
Hidvegi, A.
Hill, C.
Hill, G. C.
Hoffman, K. D.
Hoshina, K.
Hou, W.
Huber, T.
Hultqvist, K.
Hünnefeld, M.
Hussain, R.
Hymon, K.
In, S.
Iovine, N.
Ishihara, A.
Jansson, M.
Japaridze, G. S.
Jeong, M.
Jin, M.
Jones, B. J. P.
Kang, D.
Kang, W.
Kang, X.
Kappes, A.
Kappesser, D.
Kardum, L.
Karg, T.
Karl, M.
Karle, A.
Katz, U.
Kauer, M.
Kelley, J. L.
Kheirandish, A.
Kin, K.
Kiryluk, J.
Klein, S. R.
Kochocki, A.
Koirala, R.
Kolanoski, H.
Kontrimas, T.
Köpke, L.
Kopper, C.
Koskinen, D. J.
Koundal, P.
Kovacevich, M.
Kowalski, M.
Kozynets, T.
Kruiswijk, K.
Krupczak, E.
Kumar, A.
Kun, E.
Kurahashi, N.
Lad, N.
Gualda, C. Lagunas
Lamoureux, M.
Larson, M. J.
Lauber, F.
Lazar, J. P.
Lee, J. W.
DeHolton, K. Leonard
Leszczyńska, A.
Lincetto, M.
Liu, Q. R.
Liubarska, M.
Lohfink, E.
Love, C.
Mariscal, C. J. Lozano
Lu, L.
Lucarelli, F.
Ludwig, A.
Luszczak, W.
Lyu, Y.
Ma, W. Y.
Madsen, J.
Mahn, K. B. M.
Makino, Y.
Mancina, S.
Sainte, W. Marie
Mariş, I. C.
Marka, S.
Marka, Z.
Marsee, M.
Martinez-Soler, I.
Maruyama, R.
Mayhew, F.
McElroy, T.
McNally, F.
Mead, J. V.
Meagher, K.
Mechbal, S.
Medina, A.
Meier, M.
Meighen-Berger, S.
Merckx, Y.
Merten, L.
Micallef, J.
Mockler, D.
Montaruli, T.
Moore, R. W.
Morii, Y.
Morse, R.
Moulai, M.
Mukherjee, T.
Naab, R.
Nagai, R.
Naumann, U.
Nayerhoda, A.
Necker, J.
Neumann, M.
Niederhausen, H.
Nisa, M. U.
Noell, A.
Nowicki, S. C.
Pollmann, A. Obertacke
Oehler, M.
Oeyen, B.
Olivas, A.
Orsoe, R.
Osborn, J.
O'Sullivan, E.
Pandya, H.
Pankova, D. V.
Park, N.
Parker, G. K.
Paudel, E. N.
Paul, L.
Heros, C. Pérez de los
Peterson, J.
Philippen, S.
Pieper, S.
Pizzuto, A.
Plum, M.
Popovych, Y.
Rodriguez, M. Prado
Pries, B.
Procter-Murphy, R.
Przybylski, G. T.
Raab, C.
Rack-Helleis, J.
Rawlins, K.
Rechav, Z.
Rehman, A.
Reichherzer, P.
Renzi, G.
Resconi, E.
Reusch, S.
Rhode, W.
Richman, M.
Riedel, B.
Roberts, E. J.
Robertson, S.
Rodan, S.
Roellinghoff, G.
Rongen, M.
Rott, C.
Ruhe, T.
Ruohan, L.
Ryckbosch, D.
Cantu, D. Rysewyk
Safa, I.
Saffer, J.
Salazar-Gallegos, D.
Sampathkumar, P.
Herrera, S. E. Sanchez
Sandrock, A.
Santander, M.
Sarkar, S.
Savelberg, J.
Savina, P.
Schaufel, M.
Schieler, H.
Schindler, S.
Schlüter, B.
Schmidt, T.
Schneider, J.
Schröder, F. G.
Schumacher, L.
Schwefer, G.
Sclafani, S.
Seckel, D.
Seunarine, S.
Sharma, A.
Shefali, S.
Shimizu, N.
Silva, M.
Skrzypek, B.
Smithers, B.
Snihur, R.
Soedingrekso, J.
Søgaard, A.
Soldin, D.
Spannfellner, C.
Spiczak, G. M.
Spiering, C.
Stamatikos, M.
Stanev, T.
Stein, R.
Stezelberger, T.
Stürwald, T.
Stuttard, T.
Sullivan, G. W.
Taboada, I.
Ter-Antonyan, S.
Thompson, W. G.
Thwaites, J.
Tilav, S.
Tollefson, K.
Tönnis, C.
Toscano, S.
Tosi, D.
Trettin, A.
Tung, C. F.
Turcotte, R.
Twagirayezu, J. P.
Ty, B.
Elorrieta, M. A. Unland
Upshaw, K.
Valtonen-Mattila, N.
Vandenbroucke, J.
van Eijndhoven, N.
Vannerom, D.
van Santen, J.
Vara, J.
Veitch-Michaelis, J.
Verpoest, S.
Veske, D.
Walck, C.
Watson, T. B.
Weaver, C.
Weigel, P.
Weindl, A.
Weldert, J.
Wendt, C.
Werthebach, J.
Weyrauch, M.
Whitehorn, N.
Wiebusch, C. H.
Willey, N.
Williams, D. R.
Wolf, M.
Wrede, G.
Wulff, J.
Xu, X. W.
Yanez, J. P.
Yildizci, E.
Yoshida, S.
Yu, S.
Yuan, T.
Zhang, Z.
Zhelnin, P.
Source :
ApJ 953 160 (2023)
Publication Year :
2022

Abstract

The understanding of novae, the thermonuclear eruptions on the surfaces of white dwarf stars in binaries, has recently undergone a major paradigm shift. Though the bolometric luminosity of novae was long thought to arise directly from photons supplied by the thermonuclear runaway, recent GeV gamma-ray observations have supported the notion that a significant portion of the luminosity could come from radiative shocks. More recently, observations of novae have lent evidence that these shocks are acceleration sites for hadrons for at least some types of novae. In this scenario, a flux of neutrinos may accompany the observed gamma rays. As the gamma rays from most novae have only been observed up to a few GeV, novae have previously not been considered as targets for neutrino telescopes, which are most sensitive at and above TeV energies. Here, we present the first search for neutrinos from novae with energies between a few GeV and 10 TeV using IceCube-DeepCore, a densely instrumented region of the IceCube Neutrino Observatory with a reduced energy threshold. We search both for a correlation between gamma-ray and neutrino emission as well as between optical and neutrino emission from novae. We find no evidence for neutrino emission from the novae considered in this analysis and set upper limits for all gamma-ray detected novae.<br />Comment: Published in ApJ. 21 pages, 11 figures. Revised figure 1, 4, 6 (left panel), 11 and table 1 accounting for missing normalization factor of 2 in the flux upper limits from the GRECO Astronomy sample. Revised figure 8 accounting for a missing factor 1/2 in the visualization of GRECO effective area

Details

Database :
arXiv
Journal :
ApJ 953 160 (2023)
Publication Type :
Report
Accession number :
edsarx.2212.06810
Document Type :
Working Paper
Full Text :
https://doi.org/10.3847/1538-4357/acdc1b