Acceleration of ultra-high-energy cosmic rays in the kiloparsec-scale jets of nearby radio galaxies

TL;DR

This study shows that kiloparsec-scale jets in nearby radio galaxies like Centaurus A can accelerate particles to ultra-high energies, potentially explaining observed cosmic ray anisotropies and spectra.

Contribution

It provides high-resolution MHD and test-particle simulations demonstrating acceleration near theoretical maximums in radio galaxy jets, linking them to UHECR observations.

Findings

Jets can accelerate particles close to maximum energy limits.

Centaurus A's jets could explain the UHECR dipole anisotropy.

Fanaroff-Riley II galaxies may account for the UHECR spectrum.

Abstract

Radio galaxies have long been considered as potential sources of ultra-high-energy cosmic rays (UHECRs). Recent analyses of the UHECR spectrum, composition, and arrival directions indicate that the nearest radio galaxy, Centaurus A, could be linked to the reported dipole anisotropy, though the mechanism underlying the acceleration remains elusive. In this Letter, we explore UHECR acceleration in the kiloparsec-scale jets of radio galaxies, exemplified by Centaurus A. Using high-resolution relativistic magneto-hydrodynamic and test-particle simulations without sub-grid physics, we investigate the acceleration of the highest-energy particles in the turbulent sheath of a fast-moving jet. Our findings demonstrate that acceleration close to the maximum theoretical expectation is possible. When extrapolated to nearby radio galaxies, our results suggest that the kiloparsec-scale jets of Centaurus A could account for the dipole anisotropy in UHECRs, while more potent Fanaroff-Riley type II radio galaxies may account for the observed UHECR spectrum with a rigidity cutoff at a few Exavolts.