Kurt Woschnagg UC Berkeley

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Neutrino Astronomy at the South Pole Latest results from IceCube Kurt Woschnagg UC Berkeley SLAC Summer Institute August 3, 2011

Neutrinos as Cosmic Messengers

Neutrinos and the Origin of Cosmic Rays Cosmic ray spectrum Galactic: SN remnants Extragalactic: AGNs / GRBs / Other We expect high-energy neutrinos from the same sources: p + p fi p +... fin +... or p + g CMB fi D fi p + n fin +... E p > 6 10 19 ev GZK cutoff Greisen, Zatsepin, and Kuzmin (1966) GZK neutrinos are guaranteed

Size matters: need for a km 3 neutrino detector Rate = Neutrino flux x Neutrino Effective Area = Neutrino flux x Neutrino Cross Section x Absorption in Earth x Size of detector x (Range of muon for n m ) S.Klein, F. Halzen, Phys. Today, May 2008 Effective area (m 2 ) n m vertical horizontal Expected GZK neutrino rates in 1 km 3 detector: ~ 1 per year

Amundsen-Scott Station (US) Counting house Geographical South Pole Drill Camp DeepCore footprint

The IceCube Neutrino Observatory 2004: Project Start 1 string 2011: Project completion 86 strings 8 Configuration chronology 2006: IC9 2007: IC22 2008: IC40 2009: IC59 2010: IC79 2011: IC86 DeepCore 8 strings spacing optimized for lower energies 480 optical sensors PMT Digital Optical Module (DOM)

Neutrino Detection Principle Observe the charged secondaries via Cherenkov radiation detected by a 3D array of optical sensors ν l W, Z l, ν l hadronic shower Need a huge volume (km 3 ) of an optically transparent detector material g Antarctic ice is the most transparent natural solid known (absorption lengths up 200 m) m n

Neutrino Event Signatures Tracks n m + N fim + X pointing resolution ~1 o Cascades e-m and hadronic cascades n e(t) + N fie(t) + X n f + N fin f + X f = e, m,t energy resolution 10% in log(e) Composites starting tracks tau double bangs good directional and energy resolution

Up-going muon: signature of n m event IC22

Cascade candidate: signature of n e event IC22 Reconstructed energy = 134 TeV arxiv: 1101.1692

In the Shadow of the Moon Cosmic rays blocked by the moon cause point-like deficit in angular distribution of down-going muons in the detector on-source IC59 preliminary off-source left off-source right Moon shadow seen with ~10s Systematic pointing error < 0.1 o Verification of PSF for track reco. Need high statistics and good angular resolution!

Atmospheric Neutrinos IC40 IceCube ν μ spectrum up to 400 TeV Phys. Rev. D83 (2011) 012001

Search for Neutrino Point Sources Search for an excess of astrophysical neutrinos from a common direction over a background of atmospheric neutrinos Atm. n Atm. m

All-Sky Point Source Search IC40+IC59 Northern Sky (below the horizon) Data dominated by atmos. n s E ~ 10 s - 100 s of TeV E -2 neutrino simulation Southern Sky (above the horizon) Data dominated by atmos. m s E > PeV, increasing with angle More than 107,000 events: 43,339 upgoing + 64,230 downgoing Livetime: 348 days (IC59) + 375 days (IC40)

All-Sky Point Source Search atmospheric n PRELIMINARY IC40+IC59 atmospheric m significance

All-Sky Point Source Search atmospheric n PRELIMINARY IC40+IC59 atmospheric m significance Hottest spot (Ra=75.45, Dec=-18.15) -log 10 p = 4.65 nsrc best = 18.3 g best = 3.9 Highest significance in azimuthally scrambled skymaps (2000 trials) Not significant: 74.2% of trials have significance hottest spot -log 10 p

All-Sky Point Source Search Atmos. neutrinos PRELIMINARY IC40+IC59 Atmos. muons significance Hottest spot (Ra=75.45, Dec=-18.15) -log 10 p = 4.65 nsrc best = 18.3 g best = 3.9 Highest significance in azimuthally scrambled skymaps (2000 trials) Not significant: 74.2% of trials have significance hottest spot -log 10 p

Searches for a Diffuse Neutrino Flux Diffuse Flux = effective sum from all (unresolved) extraterrestrial sources (e.g., AGNs) Possibility to observe diffuse signal even if flux from any individual source is too weak for detection as a point source Search for excess of astrophysical neutrinos with a harder spectrum than background atmospheric neutrinos Atmospheric n, m Astro. n Harder Spectrum n (E -2 ) Energy Advantage over point source search: can detect weaker fluxes Atm. n Disadvantages: high background must simulate background precisely Sensitive to all three neutrino flavors Atm. m

Limits on a diffuse muon neutrino flux Experimental upper limits on the diffuse flux of muon neutrinos from sources with F ~ E -2 energy spectrum IC40 Waxman-Bahcall bound (neutrino upper bound from cosmic rays flux under certain assumptions) IceCube, arxiv: 1104.5187

Limits on a diffuse neutrino flux: cascades Experimental upper limits on the diffuse flux of neutrinos from sources with F ~ E -2 energy spectrum AMANDA (1001d) Astropart. Phys. 34 (2011) 420 IC22 (257d) arxiv: 1101.1692 Waxman-Bahcall bound Improvements expected with a larger detector IC40 sensitivity (337d)

Extremely High-Energy Cosmic Neutrino Fluxes Phys. Rev. D83 (2011) 092003 GZK n models The world s best all-flavor n upper limits to date from 10 6 to 10 10 GeV

Cosmic Ray Anisotropy Observation of anisotropy in the arrival directions of cosmic rays IC59 0 o 360 o IC40 IC22 Relative Intensity Year Rate (Hz) LiveTime CR Median Energy Right Ascension not 180 between min/max not a dipole Median Angular Resolution Events 2007 (IC22) 240 ~226 days ~19 TeV 3 4 10 9 2008 (IC40) 780 ~324 days ~19 TeV 3 1.9 10 10 2009 (IC59) 1200 ~324 days ~19 TeV 3 3.3 10 10

Cosmic Ray Anisotropy Anisotropy seen in Southern Sky by IceCube is continuation of anisotropy seen in Northern Sky Preliminary Cause of anisotropy not known. Speculations include: Isolated nearby and recent SNR (unlikely) Configuration of magnetic fields in or near solar system Compton-Getting effect (not consistent with data) Further studies of anisotropy vs energy, angular scale, time variability, spectral properties,

Indirect Dark Matter Searches Search for neutrinos from objects where Dark Matter can have accumulated gravitationally over the evolution of the Universe: Sun, Earth, Galactic Halo, Galactic Center, dwarf spheroids WIMP (neutralino)

Indirect Dark Matter Search: Solar WIMPs Data collected when the Sun is below the horizon at South Pole Phys. Rev. Lett. 102 (2009) 201302 Earth IC22 90 o < Q < 113 o (for half the year) South Pole No excess of events from the Sun, observation consistent with the expected background upper limit on the number of signal events at 90% CL : m s 90% CL limit on the neutrino to muon conversion rate: 90% CL limit on the neutralino annihilation rate in the Sun: G n fim = m s V eff T G A = k -1 (c) G n fim

Indirect Dark Matter Search: Solar WIMPs IceCube/AMANDA results from 1065 days of livetime between 2001-2008

Indirect Dark Matter Search: Galactic Halo IC22 (275 days) Expected relative neutrino flux from DM self-annihilation in GH Phys. Rev. D 84 (2011) 022004 neutrino candidates No observed excess over background

Summary IceCube Neutrino Observatory completed The era of km 3 neutrino astronomy has begun Physics run with complete detector started in May, 2011 100,000+ high-energy neutrinos on the books No astrophysical neutrino sources detected yet Increased sensitivity at lower energies with DeepCore Lots of physics to come: cosmic ray spectrum cosmic ray composition cosmic ray anisotropies atmospheric neutrinos (prompt component, oscillations, effects of quantum gravity, sterile neutrinos, ) neutrino point sources gamma ray bursts GZK neutrinos multimessenger approaches diffuse n fluxes dark matter magnetic monopoles supernova bursts shadow of the moon atmospheric physics glaciology climatology new technologies for highest energies (radio, acoustics)

The IceCube Collaboration http://icecube.wisc.edu 36 institutions, ~250 members Canada University of Alberta US Bartol Research Institute, Delaware Pennsylvania State University University of California - Berkeley University of California - Irvine Clark-Atlanta University University of Maryland University of Wisconsin - Madison University of Wisconsin - River Falls Lawrence Berkeley National Lab. University of Kansas Southern University, Baton Rouge University of Alaska, Anchorage University of Alabama, Tuscaloosa Georgia Tech Ohio State University Sweden Uppsala Universitet Stockholms Universitet UK Oxford University Germany Universität Mainz DESY-Zeuthen Universität Dortmund Universität Wuppertal Humboldt-Universität zu Berlin MPI Heidelberg RWTH Aachen Universität Bonn Ruhr-Universität Bochum Belgium Université Libre de Bruxelles Vrije Universiteit Brussel Universiteit Gent Université de Mons-Hainaut Switzerland EPFL, Lausanne Japan Chiba University Barbados University of West Indies ANTARCTICA Amundsen-Scott Station New Zealand University of Canterbury

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