6533b7d3fe1ef96bd1260b21
RESEARCH PRODUCT
A Search for IceCube Events in the Direction of ANITA Neutrino Candidates
Icecube CollaborationM. G. AartsenM. AckermannJ. AdamsJ. A. AguilarM. AhlersM. AhrensC. AlispachK. AndeenT. AndersonI. AnsseauG. AntonC. Arg��ellesJ. AuffenbergS. AxaniP. BackesH. BagherpourX. BaiA. Balagopal V.A. BarbanoS. W. BarwickB. BastianV. BaumS. BaurR. BayJ. J. BeattyK. -H. BeckerJ. Becker TjusS. BenzviD. BerleyE. BernardiniD. Z. BessonG. BinderD. BindigE. BlaufussS. BlotC. BohmS. B��serO. BotnerJ. B��ttcherE. BourbeauJ. BourbeauF. BradascioJ. BraunS. BronJ. Brostean-kaiserA. BurgmanJ. BuscherR. S. BusseT. CarverC. ChenE. CheungD. ChirkinS. ChoiK. ClarkL. ClassenA. ColemanG. H. CollinJ. M. ConradP. CoppinP. CorreaD. F. CowenR. CrossP. DaveC. De ClercqJ. J. DelaunayH. DembinskiK. DeoskarS. De RidderP. DesiatiK. D. De VriesG. De WasseigeM. De WithT. DeyoungA. DiazJ. C. D��az-v��lezH. DujmovicM. DunkmanE. DvorakB. EberhardtT. EhrhardtP. EllerR. EngelP. A. EvensonS. FaheyA. R. FazelyJ. FeldeK. FilimonovC. FinleyD. FoxA. FranckowiakE. FriedmanA. FritzT. K. GaisserJ. GallagherE. GansterS. GarrappaL. GerhardtK. GhorbaniT. GlauchT. Gl��senkampA. GoldschmidtJ. G. GonzalezD. GrantT. Gr��goireZ. GriffithS. GriswoldM. G��nderM. G��nd��zC. HaackA. HallgrenR. HallidayL. HalveF. HalzenK. HansonA. HaungsD. HebeckerD. HeeremanP. HeixK. HelbingR. HellauerF. HenningsenS. HickfordJ. HignightG. C. HillK. D. HoffmanR. HoffmannT. HoinkaB. Hokanson-fasigK. HoshinaF. HuangM. HuberT. HuberK. HultqvistM. H��nnefeldR. HussainS. InN. IovineA. IshiharaM. JanssonG. S. JaparidzeM. JeongK. JeroB. J. P. JonesF. JonskeR. JoppeD. KangW. KangA. KappesD. KappesserT. KargM. KarlA. KarleU. KatzM. KauerJ. L. KelleyA. KheirandishJ. KimT. KintscherJ. KirylukT. KittlerS. R. KleinR. KoiralaH. KolanoskiL. K��pkeC. KopperS. KopperD. J. KoskinenM. KowalskiK. KringsG. Kr��cklN. KulaczN. KurahashiA. KyriacouJ. L. LanfranchiM. J. LarsonF. LauberJ. P. LazarK. LeonardA. Leszczy��skaM. LeuermannQ. R. LiuE. LohfinkC. J. Lozano MariscalL. LuF. LucarelliJ. L��nemannW. LuszczakY. LyuW. Y. MaJ. MadsenG. MaggiK. B. M. MahnY. MakinoP. MallikK. MallotS. MancinaI. C. Mari��R. MaruyamaK. MaseR. MaunuF. McnallyK. MeagherM. MediciA. MedinaM. MeierS. Meighen-bergerG. MerinoT. MeuresJ. MicallefD. MocklerG. Moment��T. MontaruliR. W. MooreR. MorseM. MoulaiP. MuthR. NagaiU. NaumannG. NeerH. NiederhausenM. U. NisaS. C. NowickiD. R. NygrenA. Obertacke PollmannM. OehlerA. OlivasA. O'murchadhaE. O'sullivanT. PalczewskiH. PandyaD. V. PankovaN. ParkP. PeifferC. P��rez De Los HerosS. PhilippenD. PielothS. PieperE. PinatA. PizzutoM. PlumA. PorcelliP. B. PriceG. T. PrzybylskiC. RaabA. RaissiM. RameezL. RauchK. RawlinsI. C. ReaA. RehmanR. ReimannB. RelethfordM. RenschlerG. RenziE. ResconiW. RhodeM. RichmanS. RobertsonM. RongenC. RottT. RuheD. RyckboschD. RysewykI. SafaS. E. Sanchez HerreraA. SandrockJ. SandroosM. SantanderS. SarkarS. SarkarK. SataleckaM. SchaufelH. SchielerP. SchlunderT. SchmidtA. SchneiderJ. SchneiderF. G. Schr��derL. SchumacherS. SclafaniS. SeunarineS. ShefaliM. SilvaR. SnihurJ. SoedingreksoD. SoldinM. SongG. M. SpiczakC. SpieringJ. StachurskaM. StamatikosT. StanevR. SteinJ. StettnerA. SteuerT. StezelbergerR. G. StokstadA. St����lN. L. StrotjohannT. St��rwaldT. StuttardG. W. SullivanI. TaboadaF. TenholtS. Ter-antonyanA. TerliukS. TilavK. TollefsonL. TomankovaC. T��nnisS. ToscanoD. TosiA. TrettinM. TselengidouC. F. TungA. TurcatiR. TurcotteC. F. TurleyB. TyE. UngerM. A. Unland ElorrietaM. UsnerJ. VandenbrouckeW. Van DriesscheD. Van EijkN. Van EijndhovenJ. Van SantenS. VerpoestM. VraegheC. WalckA. WallaceM. WallraffN. WandkowskyT. B. WatsonC. WeaverA. WeindlM. J. WeissJ. WeldertC. WendtJ. WerthebachB. J. WhelanN. WhitehornK. WiebeC. H. WiebuschL. WilleD. R. WilliamsL. WillsM. WolfJ. WoodT. R. WoodK. WoschnaggG. WredeD. L. XuX. W. XuY. XuJ. P. YanezG. YodhS. YoshidaT. YuanM. Z��ckleinsubject
010504 meteorology & atmospheric sciencesPoint sourceAstrophysics::High Energy Astrophysical PhenomenaFOS: Physical sciencesAstrophysics01 natural sciencesStandard ModelHigh Energy Physics - Phenomenology (hep-ph)Tau neutrino0103 physical sciencesTRACK RECONSTRUCTIONSource spectrum010303 astronomy & astrophysics0105 earth and related environmental sciencesPhysicsHigh Energy Astrophysical Phenomena (astro-ph.HE)astro-ph.HEIsotropyAstrophysics::Instrumentation and Methods for AstrophysicsAstronomy and Astrophysicshep-phHigh Energy Physics - PhenomenologyAir showerPhysics and Astronomy13. Climate actionSpace and Planetary ScienceNeutrinoAstrophysics - High Energy Astrophysical PhenomenaEvent (particle physics)description
During the first three flights of the Antarctic Impulsive Transient Antenna (ANITA) experiment, the collaboration detected several neutrino candidates. Two of these candidate events were consistent with an ultra-high-energy up-going air shower and compatible with a tau neutrino interpretation. A third neutrino candidate event was detected in a search for Askaryan radiation in the Antarctic ice, although it is also consistent with the background expectation. The inferred emergence angle of the first two events is in tension with IceCube and ANITA limits on isotropic cosmogenic neutrino fluxes. Here, we test the hypothesis that these events are astrophysical in origin, possibly caused by a point source in the reconstructed direction. Given that any ultra-high-energy tau neutrino flux traversing the Earth should be accompanied by a secondary flux in the TeV-PeV range, we search for these secondary counterparts in seven years of IceCube data using three complementary approaches. In the absence of any significant detection, we set upper limits on the neutrino flux from potential point sources. We compare these limits to ANITA's sensitivity in the same direction and show that an astrophysical explanation of these anomalous events under standard model assumptions is severely constrained regardless of source spectrum or time profile.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-01-06 |