Case for Centaurus A as the main source of ultrahigh-energy cosmic rays

TL;DR

This paper explores Centaurus A as the primary source of ultrahigh-energy cosmic rays, analyzing source properties, composition, and magnetic deflections to explain observed spectra and anisotropies.

Contribution

It proposes that Centaurus A can account for the main features of ultrahigh-energy cosmic rays, emphasizing the role of nuclei composition and magnetic deflections.

Findings

Cosmic rays above the ankle are dominated by CNO nuclei from Centaurus A.

Heavy nuclei like Si and Fe become dominant above 70 EeV.

A mixture of C and O nuclei better explains the spectrum than a pure N component.

Abstract

We discuss the possibility that a dominant fraction of the cosmic rays above the ankle is due to a single nearby source, considering in particular the radio galaxy Centaurus A. We focus on the properties of the source spectrum and composition required to reproduce the observations, showing that the nuclei are strongly suppressed for E>10Z EeV, either by a rigidity dependent source cutoff or by the photodisintegration interactions with the CMB at the giant dipole resonance. The very mild attenuation effects at lower energies imply that the secondary nuclei from this source only provide a small contribution. Given the moderate anisotropies observed, the deflections in extragalactic and Galactic magnetic fields should play a crucial role in determining the cosmic ray arrival direction distribution. The diffusion in extragalactic fields as well as the finite source lifetime also significantly affect the shape of the observed spectrum. The cosmic ray flux at tens of EeV is dominated by the CNO component, and we show that it is actually better reproduced by a mixture of C and O nuclei rather than by the usual assumption of a N component effectively describing this mass group. The Si and Fe group components become dominant above 70 EeV, in the energy range in which a strong spectral suppression is present. If the localised flux excess appearing above 40 EeV around the Centaurus A direction is attributed to the CNO component, the He nuclei from the source in the energy range from 10 to 20 EeV could lead to a similar anisotropy unless its contribution is suppressed. The cosmic ray flux at a few EeV should mostly result from a more isotropic light component associated to a population of extragalactic sources. The inclusion of the subdominant contribution of heavy nuclei from the Galactic component helps to reproduce the observations around 1 EeV.