Ultra-High-Energy Cosmic Rays Accelerated by Magnetically Dominated Turbulence
Abstract
Ultra-High-Energy Cosmic Rays (UHECRs), particles characterized by energies exceeding 1018 eV, are generally believed to be accelerated electromagnetically in high-energy astrophysical sources. One promising mechanism of UHECR acceleration is magnetized turbulence. We demonstrate from first principles, using fully kinetic particle-in-cell simulations, that magnetically dominated turbulence accelerates particles on a short timescale, producing a power-law energy distribution with a rigidity-dependent, sharply defined cutoff well approximated by the form f cut(E, E cut) = sech[ ( E/E cut )2 ]. Particle escape from the turbulent accelerating region is energy-dependent, with t esc E-δ and δ 1/3. The resulting particle flux from the accelerator follows dN/dEdt E-s sech[ ( E/E cut )2 ], with s 2.1. We fit the Pierre Auger Observatory's spectrum and composition measurements, taking into account particle interactions between acceleration and detection, and show that the turbulence-associated energy cutoff is well supported by the data, with the best-fitting spectral index being s = 2.1+0.06-0.13. Our first-principles results indicate that particle acceleration by magnetically dominated turbulence may constitute the physical mechanism responsible for UHECR acceleration.
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