Ultra-high energy cosmic ray nuclei from individual magnetized sources

We investigate the dependence of composition, spectrum and angular distributions of ultra-high energy cosmic rays above 10¹⁹ eV from individual sources on their magnetization. We find that, especially for sources within a few megaparsecs of the observer, observable spectra and composition are severely modified if the source is surrounded by fields of  G on scales of a few megaparsecs. Low energy particles diffuse over larger distances during their energy loss time. This leads to considerable hardening of the spectrum up to the energy where the loss distance becomes comparable to the source distance. Magnetized sources thus have very important consequences for observations, even if cosmic rays arrive within a few degrees of the source direction. At the same time, details in spectra and chemical composition may be intrinsically unpredictable because they depend on the unknown magnetic field structure. If primaries are predominantly nuclei of atomic mass A accelerated up to a maximum energy E_max with spectra not much softer than E⁻², secondary protons from photo-disintegration can produce a conspicuous peak in the spectrum at energy . A related feature appears in the average mass dependence on energy.