Auger New Results G. Matthiae Universita’ e Sezione INFN di Roma “Tor Vergata”

1. NO – VE Venezia - April 15-18, 2008 “Un altro modo di guardare il cielo” Auger New ResultsG. MatthiaeUniversita’ e Sezione INFN di Roma “Tor Vergata”

2. Cosmic ray spectrum year 2000 ~ 1 / E3 1 particle/km2/century LHC c.m.

3. AGASA: surface array HiRes: fluorescence telescopes Auger: Hybrid Cosmic ray spectrum - 2008 l ankle GZK

4. Greisen-Zatsepin-Kuzmin Interaction with CMBGZK cutoff Above E ≈ 6*1019 eV, protons loose rapidly energy via pion photoproduction. Energy loss ≈ 15 % / interaction. Interaction length = 5 – 10 Mpc p + γ CMB → n + π+ p + π0 ∆+ production {γ from π0 , ν from π+} protons e+e– e+ e- pair production is less effective, energy loss ≈0.1% / interaction Produces a “dip” in the spectrum (Berezinsky) Attenuation length  Nuclei: also photodissociation Interaction length

5. PROTONS 1 EeV = 1018 eV

6. Horizon: maximum distance of the sources from which X % (for example 90 %) of the protons arrive on Earth with energy above a given value. Energy (EeV) 100 Mpc

7. Fluorescence Detector (FD) • Longitudinal development of the shower • Calorimetric measurement of the energy • Calibration of the energy scale • Only moonless nights • 12% duty cycle ! Auger hybrid detector • Surface Detector (SD) • Front of shower at ground • Direction and “energy” of the shower

8. nearly completed 350 S latitude ≈ 1400 m height ≈ 875 g/cm2 AUGER Observatory Total area ~3000 km2 • Surface detectors (“water tanks”) 1.5 km spacing • 24 fluorescence telescopes, 6 in each of 4 buildings • Very flat regionwith low population density • Good atmospheric conditions (clouds, aerosol)

9. Communicationantenna GPSantenna Electronics enclosure 40 MHz FADC, local triggers, 10 Watts Solar Panel three 9” PMTs Plastic tank with 12 tons of water Battery box Water Tank in the Pampa

10. Calibration: Vertical Equivalent Muon (VEM) : ~ 90 p.e. Time resolution ~ 12 ns Selecting vertical muons with telescope scintillation counters Dia Noche

11. Young & Old Shower ‘young’ shower strong e.m. component ‘old’ shower m signal dominates

12. The FD telescope(Schmidt optics)Field of view 30x30 degrees Diaphragm Spherical mirror PMT camera Shutter UV Filter (300-400 nm)

14. Camera with 440 PMTs Fluorescence Telescope Spherical mirror (R=3.4 m)

15. FD ABSOLUTE CALIBRATION Drum Drum: a calibrate light source uniformly illuminates the FD camera Mirror reflectivity, PMT sensitivity etc., are all included! ~ 5 photons /ADC 10% error

16. Atmospheric attenuation / shoot on shower technique LIDAR Backscattering Elastic bcks. molecular/Rayleigh & aerosol/Mie DAQ Laser Mirror

17. 355 nm Steerable laser SD tank optical fiber FD “TEST BEAM” Central Laser Facility Time correlation FD - SD

18. Longitudinal profile of showers from the FD telescopesFit with empirical formula of Gaisser-HillasCherenkov light subtractedCalorimetric measurement of the energy. 4 par Nmax~ E , Xmax~ log E

19. Correction for energy loss (neutrinos, muons) p / Fe : 8 – 12 % at 1019 eV (10% ± 2%) eventually important to know the composition

20. Study of composition – mass of the primaries Xmax Depth of the maximum

21. Xmax as a function of the energy Compilation previous data {

22. g A Photon – the experimental method Fluorescence Detector Xmax from shower longitudinal profile. (SD) Shower front curvature Surface Detector Shape of the front of the shower (SD) Shower front thickness A g

23. HP: Haverah Park A1,A2: AGASA Y: Yakutsk Limits on photon fraction (integral flux)PRELIMINARY ~ 3 %

24. Neutrinos - Earth skimming W L 10 km hmax

25. Auger – no neutrino candidates

26. Xmax measured over two decades of energy Syst error on Xmax < 15 g /cm2 (<A> ~ 5) Mass composition: protons, light nuclei, Fe ?

27. HiRes Final data 2007 5.1 +/- 0.7 Power law index E-γ HiRes Group: astro-ph/0703099 V. Berezinski: shallow minimum (“dip”) from e +e- production and pile-up of GZK particles

28. Auger - One event of high energy:~1020 eV, q ~60° 34 tanks Lateral Distribution Function LDF Fit distance r from the core S=A [r/rs (1+r/rs)] -β rs = 700 m A, β from fit (β= 2-2.5) S(1000) energy estimator Signal (VEM)

29. Energy calibration – hybrid eventsEnergy obtained by the calorimetric measurement of the fluorescence detector. Simulation not needed. 661 events S(1000) 6x1019 eV Corrected to 380 EFD= a x Sb b = 1.08 ± 0.04 • Error on the energy • 19 % statistical • 22% systematic (scale error) fluorescence yield/calibration

30. Energy spectrum (θ < 600)Exposure 7000 km2 sr yr (3% error) (~ 1 year Auger completed) Exp. Observed > 4x1019 179±9 75 > 1020 38±3 1 Trigger efficiency =100 % above 3x1018 eV

31. Detailed features of the spectrum better seen by taking difference with respect to reference shape Js = A x E-2.69 Fit E-γ γ = 2.69 ± 0.02 GZK cut off Slope γ above 4x1019 eV: 4.0 ± 0.4 HiRes: 5.1 ± 0.7

32. ENERGY SPECTRUM 0-60 degrees 60-80 degrees

33. Precision of the measurement of the direction Vertical shower of energy 1019 eV activates 7-8 tanks

34. EVIDENCE OF ANISOTROPY AT HIGH ENERGY High-energy events (E > 5.7x1019 eV) are correlated with AGNs at distance less than about 75 Mpc Angular correlation (~ 30) 9 November 2007

35. Véron &Véron-Cetty catalogue 442 AGN (292 in f.o.v.) z<0.018 (75 Mpc) 27 events E > 57 EeV 20 events correlate with AGN within 3.20 Galactic coordinates Relative exposure Doublet from Centaurus A (nearest AGN at ~ 4 Mpc) Border of the field of view Super-galactic plane

36. ANALYSIS METHOD Source y Probability p that one event from isotropic flux is close (<y) to at least one source p = fraction of “Auger sky” covered by windows y centred on sources Three parameter scan to find the minimum of P 1- Minimum CR energy (  N) minimize deflections in B 2- Maximum source distance zmax GZK 3- Maximum angular separation y deflections in B and angular resolution Fix candidate sources and maximum angular distance y Prob. >k of the N events from isotropic flux correlate by chance with sources (<y)

37. Set of parameters for the minimum P corresponding to maximum correlation with AGN • Angular separation ψ = 3.10 • Maximum AGN redshift ( 0.018 corresponding to ~75 Mpc) • Energy threshold : 57 EeV p = 0.21 (1.7x10-3) Probability of observed configuration if distribution is isotropic: 10-5 5 of the 7 events not correlated are close to the galactic plane

38. CR AGN ANGULAR SEPARATION FROM THE CLOSEST AGN The 6 events at low galactic latitudes |b| < 120 Isotropic flux • catalogue • incompleteness • larger deflections • in galactic B

39. Deflection in the galactic magnetic field Simulation (protons 60 EeV) 20 correlated events

42. Conclusions • Auger observes the GZK steepening of the energy spectrum confirming HiRes results (very high energy events are of extra-galactic origin). • Correlation with AGNs (E > 57 EeV). Direct evidence of extra-galactic origin. Identification of the sources. ~ 25 events/year • Interplay of different observables - Composition at very high-energy: protons or mixture of protons and light nuclei as indicated by Xmax ? <A>=5 ? • Shape of the GZK steepening. • Energy calibration (22% scale error at present) • Horizon ( calculation gives 75 Mpc  80 – 100 EeV). • Magnetic field deflection (small for protons !) More statistics and better control of the systematic errors needed ! Auger North (Colorado, US) to study northern sky (~ 20000 km2 = 7 x Auger South) FUTURE

44. Zenith angle dependence of the energy estimator S(1000)

45. Shower parameters from Fluorescence Detector (single telescope) • Determination of the Shower-Detector Plane (SDP) is good • Time fit:t(χi) = t0 + Rp*tan [(χ0 - χi)/2] • Space reconstruction is inaccurate within the Shower Detector Plane. shower t0 Rp χi χ0

46. AttenuationRayleigh attenuation length: 23 km at sea level Vertical Aerosol Optical Density VAOD (h) = ∫α(z) dz Attenuazione: exp{-VAOD(h)} Not a good night

47. Study of excess from the Galactic Center Observation of an excess from the region of the Galactic centre at the level of 4.5 σ was reported by AGASA (1.22 ± 0.05) in angular cone of 20 degree radius. The Auger Observatory is suitable for these studies because the Galactic centre (constellation of Sagittarius) lies well in the field of view of the experiment. In the Auger data there is no indication of a statistically significant excess Energy interval (eV) Nobs/Nexp Ratio (errors: stat, syst) 1017.9 -- 1018.3 3179 / 3154 1.01 ± 0.02 ± 0.01 1018 – 1018.4 2116 / 2160 0.98 ± 0.02 ± 0.01 1018.1 – 1018.5 1375 / 1395 0.99 ±0.03 ± 0.01

48. protons • Effect of interaction with CMB • V.Berezinsky et al. • production of e+ e- pairs • photoproduction of pions

49. GZK and mass composition Only protons and not too light nuclei are able to reach the Earth for energies above ~ 60 EeV