Propagation and Composition of Ultra High Energy Cosmic Rays

1. Propagation and Composition of Ultra High Energy Cosmic Rays Roberto Aloisio INFN – Laboratori Nazionali del Gran Sasso 6th Rencotres du Vientnam Challenges in Particle Astrophysics Hanoi 6-12 August 2006

2. The spectrum of CR's GZK 2nd Knee Ankle Knee

3. The first fuzzy picture of the UHECR sky Small angle clustering gives indications about the source number density CAVEAT Recently Blasi, De Marco and Olinto found a 5σ inconsistency between the spectrum and the small scale anisotropies measured by AGASA. As nS decreases (fixed flux) sources become brighter with an increase in clustering probability At most one source in the angular bin of 3 degrees! The sources should have been seen in particular at 1020 eV Correlation??? if no correlations found Bursting Sources??? or High Magnetic Fields??? or Exotic Models??? Using many realizations (MC) ns  10-5 Mpc-3 40 sources within 100 Mpc (~20 degrees between sources) Blasi & De Marco (2003) Kachelriess & Semikoz (2004)

4. Fly's Eye[Dawson et al. 98] Transition from heavy (at 1017.5 eV) to light composition (at ~1019 eV) Haverah Park[Ave et al. 2001] No more than 54% can be Iron above 1019 eV No more than 50% can be photons above 4 1019 eV Similar limits from AGASA Proton composition at E>1018 eV not disfavored by experimental observations Chemical Composition No conclusive observations at energies E>1018 eV Hires, HiresMIA, Yakutsk proton compositionFly’s Eye, Haverah Park, Akeno mixed composition Hires elongation rate

5. Adiabatic losses Universe expansion Pair production p  p e+ e- UHE Proton energy losses protons CMB Universe size 1000 Mpc log10[ latt (Mpc)] 100 Mpc Photopion production p   p 0  n  log10[ E (eV)]

6. Pair production A  A e+ e- Iron Universe size Photodisintegration A   (A-1) N  (A-2) 2N UHE Nuclei energy losses helium Universe size Pair production has no particular effect on the flux Depletion of the flux Iron E  1020 eV Helium E 1019 eV

7. Protons propagation in Intergalactic Space Continuum Energy Losses Protons lose energy but do not disappear. Fluctuations in the pγ interaction start to be important only at E>5  1019 eV. Uniform distribution of sources the UHECR sources are continuously distributed with a density ns. Blasi, De Marco, Olinto (2003) Discrete sources the UHECR sources are discretely distributed with a spacing d. model parameters γg > 2 injection power law Lp source luminosity ns (d)source density (spacing) Injection spectrum number of particles injected at the source per unit time and energy Modification factor Jpunm(E) only redshift energy losses Jp(E) total energy losses

8. UHECR proton spectrum p+ p + e+ + e– p+ N + p DIP GZK sources distribution (mainly GZK) injection spectrum (mainly DIP) way of propagation (magnetic fileds) These features depend on The energy losses suffered by protons leave their imprint on the spectrum

9. Proton Dip Experimental evidence of the Dip Best fit values: γg = 2.7 <Lp> = 4  1043 erg/s ns = 3  10-5 Mpc-3 Akeno AGASA Berezinsky et al. (2002-2005)

10. heavy nuclei fraction at E>1018 eV larger than 15% (primordial He has nHe/nH0.08) Berezinsky et al. (2004) Allard et al. (2005) RA et al. (2006) the injection spectrum has gg< 2.4 Robustness and Caveats Protons in the Dip come from large distances, up to 103 Mpc. The Dip does not depend on: inhomogeneity, discreteness of sources maximum energy at the source intergalactic magnetic fields (see later...) The interpretation of the DIP in terms ofprotons pair-productionFAILS if: RA, Berezinsky, Grigorieva (2006)

11. Diffusive shock acceleration tipically shows Maximum energy distribution If the sources are distributed over Emax: (β ≈ 1.5) The maximum acceleration energy is fixed by the geometry of the source and its magnetic field the overall UHECR generation rate has a steepening at some energy Ec (minimal Emax O(1018 eV)) Kachelriess and Semikoz (2005) RA, Berezinsky, Blasi, Grigorieva, Gazizov. (2006)

12. Energy calibration by the Dip Calibrating the energy through the Dip gives an energy shift E→ λE (fixed by χ2) λAGASA = 0.90 λHiRes = 1.21 λAuger = 1.26 NOTE: λ<1 for on-ground detectors and λ>1 for fluorescence light detectors (Auger energy calibration by the FD) Different experiments show different systematic in energy determination

13. Large Scale Structures are characterized by magnetic field produced from compression and twisting of the primordial field Voids are characterized by an appreciable magnetic field Cosmological origin Faraday rotation Magnetic field concentrated around sources, i.e. in Large Scale Structures No appreciable field in most part of the universe volume Astrophysical sources Synchrotron and ICS emission Intergalactic Magnetic Fields Very poor experimental evidences Effect of IMF on UHECR deflection isotropization diffusion

14. Numerical simulations Sigl, Miniati & Ensslin use an unconstrained simulation putting the observer * close to a cluster Dolag, Grasso, Springel & Tkachev use constrained simulations, being able to reproduce the local Universe Low B (0.1 nG in filaments and 0.01 nG in voids) Low deflection angles: < 1° at 4 1019 eV UHECR astronomy is allowed High B (100 nG in filaments and 1 nG in voids) High deflection angles: up to 20° at 1020 eV UHECR astronomy nearly impossible Numerical determination of the IMF is based on LSS and MHD simulations Puzzling results by different groups

15. The IMF effect on the UHE proton spectrum Magnetic Horizon – Low Energy Steepening The diffusive flux presents an exponential suppression at low energy and a steepening at larger energies. The low energy cut-off is due to a suppression in the maximal contributing distance (magnetic horizon), its position depends on the IMF. The steepening is independent of the IMF, it depends only on the proton energy losses and coincides with the observed 2nd Knee. The low energy behavior (E<1018 eV) depends on the diffusive regime. gg=2.7 no IMF The DIP survives also with IMF Steepening in the flux at E1018 eV 2nd Knee RA & Berezinsky (2005) Lemoine (2005)

16. Galactic Cosmic Rays Ep Rigidity models can be rigidity-confinement models or rigidity-acceleration models. The energy of spectrum bending (knee) for nucleus Z is Ez = Z Ep, where Ep » 3×1015 eV is the proton knee. For Iron EFe» 8´1016eV. proton

17. helium EHe ?

18. Kascade data 2003: seem to confirm the rigidity model. Kascade data 2005: different results with different Monte Carlo approaches in data reconstruction. Rigidity scenario not confirmed. Kascade data BUT

19. Galactic and ExtraGalactic I gg=2.7 gg=2.7 without IMF with IMF The Galactic CR spectrum ends in the energy range 1017 eV, 1018 eV. 2nd Knee appears naturally in the extragalactic proton spectrum as the steepening energy corresponding to the transition from adiabatic energy losses to pair production energy losses. This energy is universal for all propagation modes (rectilinear or diffusive): E2K»1018 eV. RA & Berezinsky (2005)

20. Galactic and ExtraGalactic II Traditionally (since 70s) the transition Galactic-ExtraGalactic CR was placed at the ankle (» 1019 eV). In this context ExtraGalactic protons start to dominate the spectrum only at the ankle energy with a more conservative injection spectrum gg » 2.0  2.2. Problems for the Galactic component Galactic acceleration: Maximum acceleration energy required is very high Emax» 1019 eV Composition: How the gap between Iron knee EFe»1017eV and the ankle (1019 eV) is filled

21. Conclusions Galactic CR (nuclei) at E ≥ 1018 eV challenge for the acceleration of CR in the Galaxy (Emax EFe) ExtraGalactic CR (protons) at E ≥ 1018 eV discovery of proton interaction with CMB confirmation of conservative models for Galactic CR models for the acceleration of UHECR with γg > 2.4 1. Is there the GZK feature? Auger will soon clarify this point. First results seem to favor the GZK picture. 2. Is there a dip? Spectrum in the range 1018 - 1019 eV could be a signature of proton interaction with CMB (as the GZK feature). 3. Where is the transition Galactic-ExtraGalactic CRs? Precise determination of the mass composition in the energy range 1018 - 1019 eV.