Model Spectrum of Ultra-High-Energy Cosmic Rays Accelerated in FR-I Radio Galaxy Jets

Abstract

Nearby radio galaxies (RGs) of Fanaroff-Riley Class I (FR-I) are considered possible sites for the production of observed ultra-high-energy cosmic rays (UHECRs). Among those, some exhibit blazar-like inner jets, while others display plume-like structures. We reproduce the flow dynamics of FR-I jets using relativistic hydrodynamic simulations. Subsequently, we track the transport and energization of cosmic ray (CR) particles within the simulated jet flows using Monte Carlo simulations. The key determinant of flow dynamics is the mean Lorentz factor of the jet-spine flow, spine. When spine several, the jet spine remains almost unimpeded, but for spine a few, substantial jet deceleration occurs. CRs gain energy mainly through diffusive shock acceleration for E1~EeV and shear acceleration for E1~EeV. The time-asymptotic energy spectrum of CRs escaping from the jet can be modeled by a double power law, transitioning from E-0.6 to E-2.6 around a break energy, Ebreak, with an exponential cutoff at Ebreakspine2. Ebreak is limited either by the Hillas confinement condition or by particle escape from the cocoon via fast spatial diffusion. The spectral slopes primarily arise from multiple episodes of shock and relativistic shear accelerations, and the confinement-escape processes within the cocoon. The exponential cutoff is determined by non-gradual shear acceleration that boosts the energy of high-energy CRs by a factor of spine2. We suggest that the model spectrum derived in this work could be employed to investigate the contribution of RGs to the observed population of UHECRs.

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