Abstract
Abstract We discuss the production of ultra-high-energy cosmic-ray (UHECR) nuclei and neutrinos from blazars. We compute the nuclear cascade in the jet for both BL Lac objects and flat-spectrum radio quasars (FSRQs), and in the ambient radiation zones for FSRQs as well. By modeling representative spectral energy distributions along the blazar sequence, two distinct regimes are identified, which we call “nuclear survival” (typically found in low-luminosity BL Lacs) and “nuclear cascade” (typically found in high-luminosity FSRQs). We quantify how the neutrino and cosmic-ray (CR) emission efficiencies evolve over the blazar sequence, and we demonstrate that neutrinos and CRs come from very different object classes. For example, high-frequency-peaked BL Lacs (HBLs) tend to produce CRs, and high-luminosity FSRQs are the more efficient neutrino emitters. This conclusion does not depend on the CR escape mechanism, for which we discuss two alternatives (diffusive and advective escape). Finally, the neutrino spectrum from blazars is shown to significantly depend on the injection composition into the jet, especially in the nuclear cascade case: Injection compositions heavier than protons lead to reduced neutrino production at the peak, which moves at the same time to lower energies. Thus, these sources will exhibit better compatibility with the observed IceCube and UHECR data.
Highlights
In spite of the experimental efforts to measure cosmic rays (CRs) at the highest energies, i.e., above 1018 eV, their origin is not yet clear
We have studied blazars as sources of ultra-high-energy cosmic-ray (UHECR) and neutrinos including the injection of isotopes heavier than hydrogen into the jet
We have identified two important regimes, depending on jet luminosity and size of the blob: In the nuclear survival regime, corresponding to low luminosities or large blob sizes, the source is found to be optically thin to photonuclear interactions
Summary
In spite of the experimental efforts to measure cosmic rays (CRs) at the highest energies, i.e., above 1018 eV, their origin is not yet clear. These ultra-high-energy CRs (UHECRs) are accelerated in extragalactic sources (Aab et al 2017a) that are not yet resolved. In this study we investigate the possibility that blazars, i.e., AGNs whose jet points in the direction of the observer, are the sources of the UHECRs and neutrinos, which are expected to be produced through interactions of CRs with photons in the source and its surroundings
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