Neutrino Astronomy with AMANDA

Similar documents
A M A N DA Antarctic Muon And Neutrino Detector Array Status and Results

Astronomy with neutrinos: AMANDA and IceCube

Exploring the high-energy universe with the AMANDA and IceCube detectors

Neutrino Astronomy at the South Pole AMANDA and IceCube

Kurt Woschnagg UC Berkeley

A search for extremely high energy neutrino flux with the 6 years of IceCube data

Mariola Lesiak-Bzdak. Results of the extraterrestrial and atmospheric neutrino-induced cascade searches with IceCube

Lawrence Berkeley National Laboratory Lawrence Berkeley National Laboratory

Search for neutralino dark matter with the AMANDA neutrino telescope

RESULTS FROM AMANDA. Carlos de los Heros Division of High Energy Physics Uppsala University. CRIS04 Catania, Italy, May 31-June 4

Catching Neutrinos with an IceCube

Neutrino Astronomy at the South Pole

The real voyage is not to travel to new landscapes, but to see with new eyes... Marcel Proust

Miami Conference December 15-20, 2011 Fort Lauderdale, FL. A.R. Fazely Southern University, Baton Rouge, LA

Measuring the neutrino mass hierarchy with atmospheric neutrinos in IceCube(-Gen2)

The IceCube Experiment. K. Mase, Chiba univ.

astronomy requires kilometer-scale detectors Super- EeV detectors: RICE, ANITA, EUSO IceCube/NEMO: kilometer-scale neutrino observatories

Cosmic Ray Physics with the IceTop Air Shower Array. Hermann Kolanoski Humboldt-Universität zu Berlin

Neutrinos as astronomical messengers

Lake Baikal: from Megaton to Gigaton. Bair Shaybonov, JINR, Dubna on behalf of the Baikal Collaboration

for the IceCube Collaboration

A Search for Point Sources of High Energy Neutrinos with AMANDA-B10

IceCube: Ultra-high Energy Neutrinos

Astroparticle Physics with IceCube

High Energy Neutrino Astronomy

Cosmic Ray Physics with the IceTop Air Shower Array. Hermann Kolanoski Humboldt-Universität zu Berlin

Neutrinos: Canaries in the Coal Mine

IceCube: Dawn of Multi-Messenger Astronomy

High Energy Neutrino Astrophysics Latest results and future prospects

arxiv: v1 [astro-ph.he] 28 Jan 2013

PoS(NOW2016)041. IceCube and High Energy Neutrinos. J. Kiryluk (for the IceCube Collaboration)

C. Spiering, CERN School Zeuthen, Sept.2003

Implications of neutrino flux limits

Search for diffuse cosmic neutrino fluxes with the ANTARES detector

Neutrino Astronomy. Ph 135 Scott Wilbur

Searches for astrophysical sources of neutrinos using cascade events in IceCube

Oscillations on Ice Tyce DeYoung Department of Physics Pennsylvania State University Exotic Physics with Neutrino Telescopes Marseilles April 5, 2013

neutrino astronomy francis halzen university of wisconsin

Physics Results from the AMANDA Neutrino Detector

High Energy Neutrino Astronomy lecture 2

THE EHE EVENT AND PROSPECTS FROM THE ICECUBE NEUTRINO OBSERVATORY. Lu Lu 千葉大

arxiv:astro-ph/ v1 18 Apr 2006

Particle Physics Beyond Laboratory Energies

Indirect Dark Matter Detection

Neutrino Telescopes in Antarctica

Possible Interpretations of IceCube High Energy Neutrinos

Understanding High Energy Neutrinos

Search for Astrophysical Neutrino Point Sources at Super-Kamiokande

IceCube - Status & First Results

IceCube Results & PINGU Perspectives

Detection of Ultra-high energy neutrinos The First Light of the high energy neutrino astronomy

High energy neutrino astronomy with the ANTARES Cherenkov telescope

IceCube. francis halzen. why would you want to build a a kilometer scale neutrino detector? IceCube: a cubic kilometer detector

an introduction What is it? Where do the lectures fit in?

NEUTRINO ASTRONOMY AT THE SOUTH POLE

Cosmic Neutrinos in IceCube. Naoko Kurahashi Neilson University of Wisconsin, Madison IceCube Collaboration

Search for a diffuse cosmic neutrino flux with ANTARES using track and cascade events

A Summary of recent Updates in the Search for Cosmic Ray Sources using the IceCube Detector

A new IceCube starting track event selection and realtime event stream

Origin of Cosmic Rays

THE LAKE BAIKAL EXPERIMENT: SELECTED RESULTS

SELECTED RESULTS OF THE ANTARES TELESCOPE AND PERSPECTIVES FOR KM3NET. D. Dornic (CPPM) on behalf the ANTARES Coll.

arxiv:astro-ph/ v1 7 Oct 1999

Multi-messenger studies of point sources using AMANDA/IceCube data and strategies

Neutrinos from the Milky Way. 18th Symposium on Astroparticle Physics in the Netherlands Erwin Visser

Searches for Dark Matter Annihilations in the Sun and Earth with IceCube and DeepCore. Matthias Danninger for the IceCube collaboration

Lessons from Neutrinos in the IceCube Deep Core Array

Mediterranean Neutrino Telescopes

neutrino astronomy francis halzen University of Wisconsin

Possible sources of very energetic neutrinos. Active Galactic Nuclei

MACRO Atmospheric Neutrinos

IceCube Review Our present status. Shigeru Yoshida Department of Physics Chiba University

IceCube & DeepCore Overview and Dark Matter Searches. Matthias Danninger for the IceCube collaboration

Gustav Wikström. for the IceCube collaboration

Particle Physics with Neutrino Telescope Aart Heijboer, Nikhef

Muon Reconstruction in IceCube

PoS(NEUTEL2017)079. Blazar origin of some IceCube events

Neutrino Radiography of the Earth with the IceCube Neutrino Observatory

Neutrino Astronomy with IceCube at the Earth's South Pole

First Light with the HAWC Gamma-Ray Observatory

Searching for Physics Beyond the Standard Model. IceCube Neutrino Observatory. with the. John Kelley for the IceCube Collaboration

High-energy neutrino detection with the ANTARES underwater erenkov telescope. Manuela Vecchi Supervisor: Prof. Antonio Capone

Supernova Neutrino Detection with IceCube

Search for high energy neutrino astrophysical sources with the ANTARES Cherenkov telescope

Neutrino astronomy with IceCube and AMANDA

Coll. Ljubljana, H.Kolanoski - IceCube Neutrino Observatory 1. Hermann Kolanoski Humboldt-Universität zu Berlin and DESY

IceCube: Physics, status and future

PoS(ICRC2017)945. In-ice self-veto techniques for IceCube-Gen2. The IceCube-Gen2 Collaboration

Detection of Ultra-high energy neutrinos The First Light of the high energy neutrino astronomy

Testing New Physics With Neutrino Astrophysics. John Beacom, The Ohio State University

PERSPECTIVES of HIGH ENERGY NEUTRINO ASTRONOMY. Paolo Lipari Vulcano 27 may 2006

EeV Neutrinos in UHECR Surface Detector Arrays:

Measurement of High Energy Neutrino Nucleon Cross Section and Astrophysical Neutrino Flux Anisotropy Study of Cascade Channel with IceCube

KM3NeT. Astro-particle and Oscillations Research with Cosmics in the Abyss (ARCA & ORCA)

THE KM3NET NEUTRINO TELESCOPE IN THE MEDITERRANEAN SEA

The Shadow of the Moon in IceCube

Sungkyunkwan University, Korea

Physics Beyond the Standard. Model with IceCube. Alex Olivas. University of Maryland. (for the IceCube Collaboration)

Recent Developments of the Real-Time Capabilities of IceCube

RESULTS FROM AMANDA. CHRISTOPHER WIEBUSCH CERN EP-Division, 1211 Geneva 23, Switzerland

Transcription:

Neutrino Astronomy with AMANDA NeSS 2002 Washington, D.C. Sep 20, 2002 Albrecht Karle University of Wisconsin-Madison karle@alizarin.physics.wisc.edu

The AMANDA Collaboration 7 US, 9 European and 1 South American institutions, ~110 members: Bartol Research Institute, University of Delaware, Newark, USA BUGH Wuppertal, Germany Universite Libre de Bruxelles, Brussels, Belgium Universidad Simon Bolivar, Caracas, Venezuela DESY-Zeuthen, Zeuthen, Germany Dept. of Technology, Kalmar University, Kalmar, Sweden Lawrence Berkeley National Laboratory, Berkeley, USA Dept. of Physics, UC Berkeley, USA Institute of Physics, University of Mainz, Mainz, Germany University of Mons-Hainaut, Mons, Belgium University of California, Irvine, CA Dept. of Physics, Pennsylvania State University, University Park, USA Physics Department, University of Wisconsin, River Falls, USA Physics Department, University of Wisconsin, Madison, USA Division of High Energy Physics, Uppsala University, Uppsala, Sweden Fysikum, Stockholm University, Stockholm, Sweden Vrije Universiteit Brussel, Brussel, Belgium

South Pole Dark sector Skiway AMANDA Dome IceCube

AMANDA 19 strings 677 Optical Modules (OM) 200 m diameter 400 m tall History: AMANDA-B10: 1997, 10 strings, 300 OM AMANDA-II: 2000, 19 strings, 677 OM

Optical sensor Deployment

AMANDA DATA Event Signatures: Muons CC muon neutrino interactions Æ Muon tracks n m + N Æ m + X

AMANDA Event Signatures: Cascades MC, 1 TeV CC electron and tau neutrino interactions: n (e,t) + N Æ (e,t) + X NC neutrino interactions: n x + N Æ n x + X Cascades

Atmospheric Muons and Neutrinos Lifetime: 135 days (AMANDA-B10) Triggered Reconstructed upgoing Pass Quality Cuts Observed Data 1,200,000,000 5000 204 Predicted Neutrinos 4574 571 273

AMANDA Neutrino Sky atmospheric neutrinos events Observed Prediction: Atmos. n Observation of atmospheric neutrinos with 10 strings in agreement with prediction. ----> AMANDA is a functioning neutrino telescope! -1-0.8-0.6-0.4-0.2-0.0 cos(zenith angle) Ref: Andres et al., Nature 2001 Ahrens et al., Phys. Rev. D. 2002 (astro/ph. )

AMANDA II: Atmospheric n s as Test Beam Selection Criteria: (N hit < 50 only) Zenith > 110 o High fit quality Uniform light deposition along track Excellent shape agreement! Less work to obtain than with A-B10 3 cuts only! 4 n/day Data MC a. b. c. d. 290 events Gradual tightening of cuts extracts atm. n signal

Point Sources Amanda II (2000) In 6 o 6 o bin, for E -2 spectrum, 10-8 cm -2 s -1 flux: ~2 signal events Data: ~1 background event Sensitivities calculated using background levels as measured from data. Skyplot is scrambled in event time for blind analysis, Plot has been released, and results will be available soon. Examples for a few candidates will be given. Equatorial coordinates: declination vs. right ascension.

Point Sources Amanda II (2000) Results for three examples of possible sources: Source candidate looked at Mrk421 Mrk501 SS433 Declination 38.2 39.8 5.0 Right ascension 11.1 16.9 19.2 F m (E>10GeV,90% c.l.)/10-15 cm -2 s -1 2.05 1.71 10.52 F n (E>10GeV,90% c.l.)/10-8 cm -2 s -1 1.28 1.06 3.49 Number of events (observed) 2 1 7 Number of events (background) 1.5 1.1 4.1 Muon sensitivity (as F m ) 1.72 1.80 6.05 Neutrino sensitivity (as F n ) 1.07 1.12 2.01 F m = Limit on integrated E -2 muon flux above 10 GeV [10-15 cm -2 s -1 ] F n = Limit on integrated E -2 neutrino flux [10-8 cm -2 s -1 ]

Compare to Mrk 501 gamma rays Field of view: Continuous 2 p sr (northern sky) AMANDA B10 limit 1997 AMANDA II limit 2000, prel. Search for Point Sources of High Energy Neutrinos with AMANDA, (AMANDA B10) to appear in Ap.J., also astro-ph/0208006

m cm -2 s -1 Super-Kamiokande astro-ph/0208006

Search for diffuse flux of h.e. n m using 1 year of AMANDA B10 Atmospheric neutrino flux (MC) Injected AGN (MC) with 10-5 E -2 GeV -1 cm -2 s -1 sr -1 Energy cut DATA Thin lines: after energy cut Number of OMs with signal E 2 F < 0.9 10-6 GeV -1 cm -2 s -1 sr -1

Same analysis for diffuse flux with AMANDA II (20%) Atmospheric neutrino flux Injected AGN with 10-5 E -2 GeV -1 cm -2 s -1 sr -1 DATA Sensitivity for 20% of AMANDA II Data is comparable to 1 year of AMANDA B10 data. PRELIMINARY Number of OM with signal per 100m of track length E 2 F < 2.0 10-6 GeV -1 cm -2 s -1 sr -1

Limit to diffuse HE n m -flux Macro Baikal AMANDA B10 Systematic error: ~2 AMANDA-II (3 y) 1 pp core AGN (Nellen) 2 pg core AGN Stecker & Salomon) 3 pg maximum model (Mannheim et al.) 4 pg blazar jets (Mannh) 5 pg AGN (Rachen & Biermann) 6 pp AGN (Mannheim) 7 GRB (Waxman & Bahcall) 8 TD (Sigl) From: Mannheim & Learned, 2000

Diffuse flux with cascade events (see slide 7 for def.) 20% Amanda II cascade limit (Y2K) Ref.: Search for Neutrino-Induced Cascades with the AMANDA Detector, subm. To Phys Rev. D., Ahrens et al. (AMANDA coll.), also: astro-ph/0206487 Unique result: Limit on all n flavors First to use full reconstruction of cascade Analysis gets easier and more competitive with muons as detector grows in size, especially at higher energies Astrophysical n s F ne+ne = 10-6 E -2 GeV cm -2 s -1 F nt+nt = 10-6 E -2 GeV cm -2 s -1 Atmospheric n s n e (CC), n e +n m (NC) Prompt charm (RQPM) Predicted events in 100% of 2000 data 5.5 3.2 Predicted events in 100% of 2000 data 0.15 0.50 Search for Neutrino-Induced Cascades with the AMANDA Detector

Off source GRB search bin GRB coincidences? GRB Position 16 s 1 hour 1 hour BKG - off time 88 BATSE bursts in 1997 BKG - off time on time GRB burst Background cuts can be loosened considerably Æ high signal efficiency No signal seen in 97 data.

A-II Sensitivity to GRB 58 bursts Feb-May 2000 Sensitivity for 2000 data: ~30 x Waxman/Bahcall 99 Figure from: Mannheim & Learned, 2000 AMANDA II 2000 data 90% limit setting potential Waxman/Bahcall 99

Dark matter: WIMP Search Limit on F m from WIMP annihilation WIMP annihilation at Earth s center, use directional handle: (Area approximate) Earth n m AMANDA m MSSM/ DarkSUSY Limits to the muon flux from WIMP annihilation in the center of the Earth with the AMANDA detector. To appear in Phys Rev D Also at: astro-ph/0202370,

Coinicidences between Surface detector and AMANDA SPASE air shower array calibration of AMANDA angular resolution and pointing! 1 km Amanda-B10 (med): ~3.5 Amanda-II (med): ~ 2 2 km absolute pointing < 1.

Mass Composition of cosmic rays at the knee preliminary uncertainties.

EHE (E 10 16 ev) Event Search EHE events very bright; many PMTs detect multiple photons vertical Sensitive to non-throughgoing events Main background: muon bundles Comparable N PMT but smaller N g Calibrate with in-situ N 2 laser Still evaluating systematic uncertainties R m 10 km. Note: At EHE energies, expect only ~horizontal events

2002 real time analysis June 14 Daily transmission ~ 1 GB via satellite Full data to tape (available next polar summer) Monitoring shifts in home labs From 02/03: Iridium connection for supernova alarm

Summary AMANDA-II provides much higher sensitivity than the 10 string array (B10) Diffuse flux: Best limits. Testing models. Diffuse flux in cascade analysis (good sensitivity for ne and nt) Diffuse EHE fluxes: 0.3 km 2 at EeV. A-II testing EeV blazar models. Point sources: Best limits. A-II much better sensitivity, preview on reults. GRB sensitivity 2000: approaching predictions Relativistic Magnetic Monopoles (not shown): Best limits (0.05 x Parker bound) WIMP search: high mass limits ~ Underground limits Monitoring Galaxy for SN bursts Cosmic Ray Composition at knee.

end

Relativistic Magnetic Monopoles 10-14 upper limit (cm -2 s -1 sr -1 ) 10-15 10-16 10-17 d electrons C - light output µ n = 1.33 (g/e) = 137 / 2 n 2 (g/e) 2 10-18 0.50 0.75 b = v/c 1.00 ª 8300 C.Spiering, n2000

Supernova Monitor Amanda B10 has monitored 60% of the Galaxy with 90% detection efficiency for a SN1987A type supernova. IceCube will monitor the full Galaxy.

SPASE - AMANDA: Energy resolution of air shower primary Log(E_true) 5 6 7 8 Proton Iron 5 6 7 8 Log(E_reconstructed) Energy resolution of air shower primary for 1<E/PeV<10: s E 7% log(e) (Mass independent; based on MC) 3500 3000 2500 2000 1500 1000 500 Entries 1798 Constant 3057. Mean -0.3207E-01 Sigma 0.6900E-01 1 PeV - 10 PeV 0-0.6-0.4-0.2 0 0.2 0.4 0.6 log(e_reconstructed)-log(e_true)

Measuring mass and energy of cosmic ray primary particle Unfolding energy and mass using SPASE and AMANDA AMANDA (number of muons) log(e/gev)

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback