Energetic particles and high-energy processes in cosmological filaments and their astronomical implications

TL;DR

This paper explores how cosmic filaments influence the propagation and confinement of high-energy cosmic rays, revealing their role as cosmic highways and reservoirs that preserve a fossil record of the universe's energetic history.

Contribution

It introduces a novel ecological framework for modeling cosmic ray interactions in filaments, considering magnetic field configurations and their impact on cosmic ray confinement and survival.

Findings

Filaments act as channels for cosmic rays between galaxies and clusters.

Filaments can trap cosmic ray protons up to 10^18 eV from voids.

Cosmic ray protons form a fossil record of the universe's energy generation.

Abstract

Large-scale cosmic filaments connect galaxies, clusters and voids. They are permeated by magnetic fields with a variety of topologies. Cosmic rays with energies up to $10^{20}\;\!{\rm eV}$ can be produced in astrophysical environments associated with star-formation and AGN activities. The fate of these cosmic rays in filaments, which cannot be directly observed on Earth, are rarely studied. We investigate the high-energy processes associated with energetic particles (cosmic rays) in filaments, adopting an ecological approach that includes galaxies, clusters/superclusters and voids as key cosmological structures in the filament ecosystem. We derive the phenomenology for modelling interfaces between filaments and these structures, and investigate how the transfer and fate of energetic cosmic ray protons are affected by the magnetism of the interfaces. We consider different magnetic field configurations in filaments and assess the implications for cosmic ray confinement and survival against hadronic pion-producing and photo-pair interactions. Our analysis shows that the fate of the particles depends on the location of their origin within a filament ecosystem, and that filaments act as `highways', channelling cosmic rays between galaxies, galaxy clusters and superclusters. Filaments can also operate as cosmic `fly paper', capturing cosmic ray protons with energies up to $10^{18}\;\!{\rm eV}$ from cosmic voids. Our analysis predicts the presence of a population of $\sim 10^{12}-10^{16}\;\!{\rm eV}$ cosmic ray protons in filaments and voids accumulated continually over cosmic time. These protons do not suffer significant energy losses through photo-pair or pion-production, nor can they be cooled efficiently. Instead, they form a cosmic ray fossil record of the power generation history of the Universe.