1 CEA mercredi 26 novembre 2007 Latest news from the Pierre Auger Observatory Nicolas G. Busca - APC - Paris 7.

Slides:

Advertisements

Similar presentations

The National Science FoundationThe Kavli Foundation APS April 2008 Meeting - St. Louis, Missouri Results from Cosmic-Ray Experiments Vasiliki Pavlidou.

Advertisements

JNM Dec Annecy, France The High Resolution Fly’s Eye John Matthews University of Utah Department of Physics and High Energy Astrophysics Institute.

Lino Miramonti - Kathmandu October Lino Miramonti Università degli Studi di Milano and Istituto Nazionale di Fisica Nucleare.

Status of Top-Down Models for the Origin of Ultra-High Energy Cosmic Rays I. Observation of ultra-high energy cosmic rays before the Pierre Auger Observatory.

Results from the Telescope Array experiment H. Tokuno Tokyo Tech The Telescope Array Collaboration 1.

GZK Horizons and the Recent Pierre Auger Result on the Anisotropy of Highest-energy Cosmic Ray Sources Chia-Chun Lu Institute of Physics, National Chiao-Tung.

Ultrahigh Energy Cosmic Ray Nuclei and Neutrinos

An update on the High Energy End of the Cosmic Ray spectra M. Ave.

Magnetic Field Workshop November 2007 Constraints on Astrophysical Magnetic Fields from UHE Cosmic Rays Roger Clay, University of Adelaide based on work.

The Pierre Auger Observatory Nicolás G. Busca Fermilab-University of Chicago FNAL User’s Meeting, May 2006.

Angela V. Olinto The University of Chicago Anisotropies at the Highest Energies.

AGASA update M. Teshima ICRR, U of CfCP mini workshop Oct

The Telescope Array Low Energy Extension (TALE)‏ Pierre Sokolsky University of Utah.

The Highest Energy Cosmic Rays Two Large Air Shower Detectors

07/05/2003 Valencia1 The Ultra-High Energy Cosmic Rays Introduction Data Acceleration and propagation Numerical Simulations (Results) Conclusions Isola.

TAUP 2005: Zaragoza Observations of Ultra-high Energy Cosmic Rays Alan Watson University of Leeds Spokesperson for Pierre Auger Observatory

Ultra high energy cosmic rays: highlights of recent results J. Matthews Pierre Auger Observatory Louisiana State University 19 August August.

16 June 2005Auger - GC Workshop Auger potentiality and analysis methods to study the Galactic Center E. Armengaud (APC/IAP) Auger Collaboration.

The National Science FoundationThe Kavli Foundation Mapping the Ultra-high--energy Cosmic-ray Sky with the Pierre Auger Observatory Vasiliki Pavlidou for.

Recent results from Pierre Auger Observatory J. R. T. de Mello Neto Universidade Federal do Rio de Janeiro XI International Conference on Hadron Spectroscopy.

Antoine Letessier-SelvonBlois - 21/05/ Auger Collaboration Anisotropy of the Highest Energy Cosmic Rays 3.7 years of surface array data from the.

Probing Extreme Universe through Ultra-High Energy Cosmic Ray Yamamoto Tokonatsu Konan University, Japan Introduction UHECR observation Recent results.

La nascita della astronomia dei raggi cosmici? Indicazioni dall' Osservatorio P. Auger Aurelio F. Grillo Teramo 8/05/08.

Paul Sommers Penn State Brookhaven, January 29, 2008 Astroparticle Physics.

Design and status of the Pierre Auger Observatory J. C. Arteaga Velázquez 1, Rebeca López 2, R. Pelayo 1 and Arnulfo Zepeda 1 1 Departamento de Física,

, A possible origin of ultra-high energy cosmic rays: collisions of two galaxies The main goal of the Pierre Auger Project is a detailed study of the energy.

Very Large Volume Neutrino Telescope Workshop Athens 13 – 15 October 2009 Recent Results on Ultra High Energy Cosmic Rays Alan Watson University of Leeds.

The Status of the Pierre Auger Observatory Bruce Dawson University of Adelaide, Australia for the Pierre Auger Observatory Collaboration.

Telescope Array Experiment: Status and Prospects Pierre Sokolsky University of Utah.

Ultra High Energy Cosmic Rays -- Origin and Propagation of UHECRs -- M.Teshima Max-Planck-Institut f ü r Physik, M ü nchen Erice Summer School July

Humberto Salazar (FCFM-BUAP) for the Pierre Auger Collaboration, CTEQ- Fermilab School Lima, Peru, August 2012 Ultrahigh Cosmic Rays: The highest energy.

Paul Sommers Fermilab PAC Nov 12, 2009 Auger Science South and North.

Claudio Di Giulio University of Roma Tor Vergata, INFN of Roma Tor Vergata IDAPP 2D Meeting, Ferrara, May The origin and nature of cosmic rays above.

Correlation of the UHECR with AGN using the new statistical test methods and the updated data from Pierre Auger Observatory Hang Bae Kim (Hanyang Univ.)

Energy Spectrum C. O. Escobar Pierre Auger Director’s Review December /15/2011Fermilab Director's Review1.

ICHEP `06, Moscow The Auger project – status and results G. Matthiae University and Sezione INFN of Roma “Tor Vergata” Study of the highest energy cosmic.

Pierre Auger Observatory for UHE Cosmic Rays Gianni Navarra (INFN-University of Torino) for the Pierre Auger Collaboration XXXXth Rencontres de Moriond.

AGASA Results Masahiro Teshima for AGASA collaboration

Ultra High Energy Cosmic Rays at Pierre Auger Observatory

P.Auger, a major step: Need high statistics large detection area : 2 x3000 km² Uniform sky coverage 2 sites located in each hemisphere Argentina and USA.

HiRes 5Y Operations – Program and Context What Physics Will be Done? How Does it Compare With Other Projects?

Stefano Argirò 1 for the Auger Collaboration 1 University of Torino, Italy, and INFN Physics case The Auger Observatory Performance Preliminary Analysis.

Pierre AUGER Observatory Jan Ridky Institute of Physics AS CR For Pierre Auger collaboration.

Future Plans and Summary Gordon Thomson Rutgers University.

The Pierre Auger Observatory (Cosmic Rays of Ultra-High Energy) The puzzle of UHECR Principle and advantages of an hybrid detector Present status of the.

for the Pierre Auger Collaboration

1 João Espadanal, Patricia Gonçalves, Mário Pimenta Santiago de Compostela 3 rd IDPASC school Auger LIP Group 3D simulation Of Extensive Air.

The Auger Observatory for High-Energy Cosmic Rays G.Matthiae University of Roma II and INFN For the Pierre Auger Collaboration The physics case Pierre.

Where do ultra-high energy cosmic rays come from? No one knows the origin of ultra-high energy cosmic rays. The majority of low-energy cosmic ray particles.

Astroparticle physics with large neutrino detectors  Existing detectors  Physics motivation  Antares project  KM3NeT proposal M. de Jong.

Status of the Pierre Auger Observatory Aaron S. Chou Fermilab Fermilab Users’ Meeting June 3, 2003.

52° Congresso SAIt 2008 Raffaella Bonino* for the Pierre Auger Collaboration ( * ) IFSI – INFN – Università di Torino.

Particle Physics with High Energy Cosmic Rays Mário Pimenta Lisboa, April 2012.

Geant4 Simulation of the Pierre Auger Fluorescence Detector

Recent Results from the HiRes Experiment Chad Finley UW Madison for the HiRes Collaboration TeV Particle Astrophysics II Madison WI 2006 August 28.

Ruben Conceição for the Pierre Auger Collaboration TAM, Venice, March 7 th 2013 The Pierre Auger Observatory Results on the highest energies.

AGASA Results Masahiro Teshima Max-Planck-Institut für Physik, München, Germany for AGASA collaboration.

L. CazónHadron-Hadron & Cosmic-Rays interactions at multi-TeV energies. Trento,2-Dez Results from the Pierre Auger Observatory L. Cazon, for the.

Bianca Keilhauer for the Pierre Auger Collaboration

Jim Matthews Louisiana State University Results from the Pierre Auger Observatory ECRS, Moscow, 4 July

1 A. Zech, Instrumentation in High Energy Astrophysics Chapter 6.3: Ultra-high energy cosmic rays & indirect detection.

Search for Anisotropy with the Pierre Auger Observatory Matthias Leuthold for the Pierre Auger Collaboration EPS Manchester 2007.

HiRes 5Y Operations – Program and Context

Anisotropy of the Highest Energy Cosmic Rays

MEASUREMENTS OF COSMIC RAYS WITH PRIMARY ENERGIES UP TO 1020 eV

TREND workshop agenda 0. Introduction and round-table

Theoretical status of high energy cosmic rays and neutrinos

Pierre Auger Observatory Present and Future

The Aperture and Precision of the Auger Observatory

Studies and results at Pierre Auger Observatory

Presentation transcript:

1 CEA mercredi 26 novembre 2007 Latest news from the Pierre Auger Observatory Nicolas G. Busca - APC - Paris 7

2 Cosmic Rays Highly energetic particles that constantly fall on the Earth ( over 1000 cosmic rays went through my body since I started talking ) Credit: S. Swordy discovered in ~1910s mixture of nuclei at low energies composition is not known at higher energies sources are still not identified

3 Tevatron Auger Regular power law ~ E -3 Low Energies: direct measurements Composition: Nuclei origin: Galactic, SNR? energy (eV) Flux (m 2 sr s GeV) -1 LHC by S. Swordy Direct Measurements (balloons, satellites) Cosmic Rays

4 Tevatron Auger Composition? Sources? energy (eV) Flux (m 2 sr s GeV) -1 LHC by S. Swordy High Energy Direct Measurements (balloons, satellites) Indirect Measurements (ground based) Cosmic Rays Regular power law ~ E -3 Low Energies: direct measurements Composition: Nuclei origin: Galactic, SNR?

5 Tevatron Auger Composition? Sources? energy (eV) Flux (m 2 sr s GeV) -1 LHC by S. Swordy High Energy GZK? (1 particle per km 2 -century) Direct Measurements (balloons, satellites) Indirect Measurements (ground based) Ultra High Energy Composition? Sources? Cosmic Rays Regular power law ~ E -3 Low Energies: direct measurements Composition: Nuclei origin: Galactic, SNR?

6 Y (Mpc) X (Mpc) The magnetic rigidity increases with E The trajectory is ballistic for E > eV Cosmic Rays: why high energy?

7 Greisen, Zatzepin & Kus’min (1966) - Interaction with the CMB background Cosmic Rays: why high energy? E th ~ 5x10 19 eV

8 Cosmic Rays: why high energy? E th ~ 5x10 19 eV GZK threshold Greisen, Zatzepin & Kus’min (1966) - Interaction with the CMB background

9 Interaction with the CMB background Cosmic Rays: why high energy? E th ~ 5x10 19 eV Flux from uniformly distributed sources (MC) proton primaries Q(E) ~ E -2.7 GZK cutoff Auger

10 Interaction with the CMB background Cosmic Rays: why high energy? E th ~ 5x10 19 eV Flux from uniformly distributed sources (MC) proton primaries Q(E) ~ E -2.7 GZK cutoff All universe Local universe GZK cutoff is NOT a sharp cutoff!! Auger

11 Expected sky at eVExpected sky at eV Sources can be discriminated We observe the entire universe, still isotropic!! Cosmic Rays: why high energy?

12 Observatorio Pierre Auger Av. San Martín Norte 304 Malargüe, (5613) Mendoza Argentina Southern Site: 3000 km 2 (10 fois Paris) A surface detector (SD): 1600 water Cherenkov detector ~100 % duty cycle large collecting area (3000 km 2 ) A fluorescence detector (FD) 4 Eyes ~10% duty cycle (only moonless clear nights)

13

14

15

16

17

18

19

20 photonselectrons/positrons muonsneutrons

21 Detection SD FD fluorescence photons  Y dE/dX fluorescence yieldenergy deposit

22 Detection: a local station radio antenna solar panel battery box GPS electronics PMT purified water A tank is a stand alone self calibrating unit (can’t wire 3000 km 2 ) vertical muon PMT Tank full of water Unit of signal = VEM = signal of a vertical muon

23 Event Reconstruction: SD Direction from timing t0t0+d/c sin(  )ddt0+2d/c sin(  )  S(1000) from signal sizes S(1000) Lateral distribution function

24 The FD Sketch of a fluorescence telescope: spherical mirror camera Diaphragm + UV filter The camera: 440 pmt (1.5deg each) 100 ns FADC 4 buildings with 6 telescopes each

25 Event Reconstruction: FD Highest signal tank pixels photons = G. Y. dE/dX X max

26 Energy Calibration Constant Intensity Cut

27 Energy Calibration Signal attenuation (CIC) f(  ) Energy calibration log 10 (E) = A + B log 10 (S 38 )

28 Publicity 1% of Auger events are public and available on :

29 Results: spectrum Auger: direct measurement of energy, geometric aperture HiRes I-II: fluorescence telescopes: aperture from MC AGASA: surface array (energy calibration from MC)

30 Results: spectrum E agasa -35% E HiRes -15% GZK cutoff observed with 6  significance Auger: direct measurement of energy, geometric aperture HiRes I-II: fluorescence telescopes: aperture from MC AGASA: surface array (energy calibration from MC)

31 Spectrum interpretation

32 Results: Composition X max Method:

33 Results: Composition

34 Results: Neutrino Limits “young” signal “old” signal

35 Results: Neutrino Limits

36 Results: Photon Limits

37 Possible sources of UHECRs Hillas diagram Log L [km] Log B [G] Hillas diagram : Acceleration limited by size and magnetic field E max r L = E/(Z.B) < L Larmor radius Size of the accelerator Not take into accound : acceleration mechanism energy losses

38 Possible sources of UHECRs Hillas diagram Log L [km] Log B [G] Hillas diagram : Acceleration limited by size and magnetic field E max r L = E/(Z.B) < L Larmor radius Size of the accelerator Not take into accound : acceleration mechanism energy losses AGN

39 Results: Anisotropies The analysis: Two stages: before May 26th exploration after May 26th confirmation prescription Nov. 2007

40 Anisotropies : Exploration Compared the data with the Veron-Cetty & Veron 12th catalogue of AGN: Correlation: angle(AGN,data)<  cut AGNs: up to D<D max Data: E>E min P iso is minimized with respect to  cut, D max and E min Results:  cut = 3.1 o, D max = 75 Mpc, E min =56 EeV Correlation: 12/15 (expected from isotropy: 3.2/15) p = probability of falling within  cut from an AGN

41 Anisotropies : Prescription For each event after 26 May 2006: check if it correlates with an AGN for fixed parameters  cut = 3.1 o, D max = 75 Mpc, E min =56 EeV (« running prescription ») if the number of correlations is above a predefined threshold, the prescription is said to pass (Decided on may 26th 2006)

42 Anisotropies : Prescription For each event after 26 May 2006: check if it correlates with an AGN for fixed parameters  cut = 3.1 o, D max = 75 Mpc, E min =56 EeV (« running prescription ») if the number of correlations is above a predefined threshold, the prescription is said to pass The prescription had a 1% chance of passing for an isotropic flux (Decided on may 26th 2006)

43 On August 31st 2007, the prescription passed (8/13) (isotropic probability 8/13 ~ 2x10 -3 ) The signal was confirmed on an independent data set Anisotropies : Confirmation

44 Anisotropies : Results Auger events Sky covered by Auger AGNs Total of 20/27 correlating (isotropy : 5.6)

45 Anisotropies : Results Smoothed VC catalog: galactic coordinates 50 Mpc 100 Mpc150 Mpc 200 Mpc250 Mpc300 Mpc 350 Mpc400 Mpc 450 Mpc

46 Anisotropies : Results Auger events Sky covered by Auger AGNs Total of 20/27 correlating (isotropy : 5.6) 19/21 cutting off the Gal. Plane

47 Anisotropies : astrophysical objects Equatorial coordinates

48 Anisotropies : Results What do these results mean? UHECRs don’t come from an isotropic distribution UHECRs come from the direction of an AGN (extragalactic origin) This does not mean that: AGNs accelerate UHECRs We’ve found the sources of UHECRs

49 The Future Near: months: ~ three papers describing anisotropies in more technical detail Middle-term: 1 year and a half: Auger will double the statistics

50 The Future Long Term Years: Larger scale detectors, Auger North (7xA.S.), EUSO, etc. UHECRs astronomy VLA (Radio) HESS (Gamma) AUGER?