Ultra High Energy Cosmic Rays

TL;DR

This paper reviews the nature, sources, and acceleration mechanisms of Ultra High Energy Cosmic Rays, highlighting recent progress and the potential of multimessenger astronomy to solve longstanding mysteries.

Contribution

It provides a comprehensive overview of UHECR properties, sources, and acceleration theories, emphasizing recent observational findings and future prospects with multimessenger approaches.

Findings

Heavy nuclei dominate the highest energy UHECRs.

A significant dipole anisotropy has been observed.

UHECR luminosity density constrains source models.

Abstract

Ultra High Energy Cosmic Rays, UHECR, are charged particles with energies between $\sim10^{18}\,{\rm eV}$ and $\sim3\times10^{20}\,{\rm eV}\sim50\,{\rm J}$. They exhibit fundamental physics at energies inaccessible to terrestrial accelerators, challenge experimental physics and connect strongly to astronomical observations through electromagnetic, neutrino and even gravitational wave channels. There has been much theoretical and observational progress in the sixty years that have elapsed since the discovery of UHECR, to divine their nature and identify their sources. The highest energy UHECR appear to be heavy nuclei with rigidity extending up to $\sim10\,{\rm EV}$; A significant ($6.9\sigma$) dipole anisotropy has been measured but our poor understanding of the Galactic magnetic fields makes this hard to interpret; The UHECR luminosity density is $\sim 10^{44}$ erg Mpc$^{-3}$ yr$^{-1}$ which constrains explanations of their origin; The most promising acceleration mechanisms involve diffusive shock acceleration and unipolar induction; The most promising sources include intergalactic accretion shocks, and relativistic jets from stellar-mass or supermassive black holes. We explore the prospects for using the highest energy events, combined with multimessenger astronomy, to help us solve the riddle of UHECR.