Closing the net on transient sources of ultra-high-energy cosmic rays

TL;DR

This paper models the sources of ultra-high-energy cosmic rays as transient events, using matter distribution and magnetic field data to constrain their properties, and identifies long gamma-ray bursts as the likely sources.

Contribution

It introduces a novel 3D matter distribution model combined with magnetic field data to constrain transient UHECR sources and identifies long gamma-ray bursts as the primary candidates.

Findings

Local Sheet is key to UHECR burst duration.

Turbulence amplitude must be 0.5-20 nG.

Burst-rate density constraints match observed excesses.

Abstract

Arrival directions of ultra-high-energy cosmic rays (UHECRs) observed above $4\times10^{19}\,$eV provide evidence of localized excesses that are key to identifying their sources. We leverage the 3D matter distribution from optical and infrared surveys as a density model of UHECR sources, which are considered to be transient. Agreement of the sky model with UHECR data imposes constraints on both the emission rate per unit matter and the time spread induced by encountered turbulent magnetic fields. Based on radio measurements of cosmic magnetism, we identify the Local Sheet as the magnetized structure responsible for the kiloyear duration of UHECR bursts for an observer on Earth and find that the turbulence amplitude must be within $0.5-20\,$nG for a coherence length of $10\,$kpc. At the same time, the burst-rate density must be above $50\,$Gpc$^{-3}\,$yr$^{-1}$ for Local-Sheet galaxies to reproduce the UHECR excesses and below $5\,000\,$Gpc$^{-3}\,$yr$^{-1}$ ($30\,000\,$Gpc$^{-3}\,$yr$^{-1}$) for the Milky Way (Local-Group galaxies) not to outshine other galaxies. For the transient emissions of protons and nuclei to match the energy spectra of UHECRs, the kinetic energy of the outflows responsible for UHECR acceleration must be below $4\times10^{54}\,$erg and above $5\times10^{50}\,$erg ($2\times10^{49}\,$erg) if we consider the Milky Way (or not). The only stellar-sized transients that satisfy both Hillas' and our criteria are long gamma-ray bursts.