838 research outputs found
On the significance of the observed clustering of ultra-high energy cosmic rays
Three pairs of possibly correlated ultra-high energy cosmic ray events were
reported by Hayashida et al (1996). Here we calculate the propagation of the
corresponding particles through both the intergalactic and galactic magnetic
fields. The large scale disc and halo magnetic components are approximated by
the models of Stanev (1997). The intergalactic magnetic field intensity is
modulated by the actual density of luminous matter along the corresponding
lines of sight, calculated from the CfA redshift catalogue (Huchra et al,
1995). The results indicate that, if the events of each pair had a common
source and were simultaneously produced, they either originated inside the
galactic halo or otherwise very unlikely events were observed. On the other
hand, an estimate of the arrival probability of ultra-high energy cosmic rays,
under the assumption that the distribution of luminous matter in the nearby
universe traces the distribution of the sources of the particles and intensity
of the intergalactic magnetic field, suggests that the pairs are chance
clusterings.Comment: Ap. J. Letters Accepted - 13 pages + 4 figure
Ensemble fluctuations of the cosmic ray energy spectrum and the intergalactic magnetic field
The origin of the most energetic cosmic ray particles is one of the most
important open problems in astrophysics. Despite a big experimental effort done
in the past years, the sources of these very energetic particles remain
unidentified. Therefore, their distribution on the Universe and even their
space density are still unknown. It has been shown that different spatial
configurations of the sources lead to different energy spectra and composition
profiles (in the case of sources injecting heavy nuclei) at Earth. These
ensemble fluctuations are more important at the highest energies because only
nearby sources, which are necessarily few, can contribute to the flux observed
at Earth. This is due to the interaction of the cosmic rays with the low energy
photons of the radiation field, present in the intergalactic medium, during
propagation. It is believed that the intergalactic medium is permeated by a
turbulent magnetic field. Although at present it is still unknown, there are
several constraints for its intensity and coherence length obtained from
different observational techniques. Charged cosmic rays are affected by the
intergalactic magnetic field because of the bending of their trajectories
during propagation through the intergalactic medium. In this work, the
influence of the intergalactic magnetic field on the ensemble fluctuations is
studied. Sources injecting only protons and only iron nuclei are considered.
The ensemble fluctuations are studied for different values of the density of
sources compatible with the constraints recently obtained from cosmic ray data.
Also, the possible detection of the ensemble fluctuations in the context of the
future JEM-EUSO mission is discussed.Comment: Accepted for publication in Physical Review
On the possibility of neutrino flavor identification at the highest energies
High energy astrophysical neutrinos carry relevant information about the
origin and propagation of cosmic rays. They can be created as a by-product of
the interactions of cosmic rays in the sources and during propagation of these
high energy particles through the intergalactic medium. The determination of
flavor composition in this high energy flux is important because it presents a
unique chance to probe our understanding of neutrino flavor oscillations at
gamma factors >10^21. In this work we develop a new statistical technique to
study the flavor composition of the incident neutrino flux, which is based on
the multipeak structure of the longitudinal profiles of very deep electron and
tau neutrino horizontal air showers. Although these longitudinal profiles can
be observed by means of fluorescence telescopes placed over the Earth's
surface, orbital detectors are more suitable for neutrino observations owing to
their much larger aperture. Therefore, we focus on the high energy region of
the neutrino spectrum relevant for observations with orbital detectors like the
planned JEM-EUSO telescope.Comment: Accepted for publication in Physical Review
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