Preheating of the Universe by cosmic rays from primordial supernovae at the beginning of cosmic reionization

TL;DR

This paper proposes that cosmic rays from primordial supernova remnants could have significantly heated the early intergalactic medium before the epoch of reionization, influencing the 21-cm signal observed today.

Contribution

It introduces a novel heating mechanism for the early IGM via cosmic rays from Population III supernovae, complementing existing models involving X-ray heating from black holes.

Findings

Cosmic rays from early supernovae could heat the IGM by 10-100 K by redshift ~15.

This heating mechanism predates and potentially influences the 21-cm signals from the epoch of reionization.

Future observations could constrain early supernova energetics and primordial magnetic fields.

Abstract

The 21-cm signal from the cosmic reionization epoch can shed light on the history of heating of the primordial intergalactic medium (IGM) at z~30-10. It has been suggested that X-rays from the first accreting black holes could significantly heat the Universe at these early epochs. Here we propose another IGM heating mechanism associated with the first stars. As known from previous work, the remnants of powerful supernovae (SNe) ending the lives of massive Population III stars could readily expand out of their host dark matter minihalos into the surrounding IGM, aided by the preceeding photoevaporation of the halo's gas by the UV radiation from the progenitor star. We argue that during the evolution of such a remnant a significant fraction of the SN kinetic energy can be put into low-energy (E<30 MeV) cosmic rays that will eventually escape into the IGM. These subrelativistic cosmic rays could propagate through the Universe and heat the IGM by ~10-100 K by z~15, before more powerful reionization/heating mechanisms associated with the first galaxies and quasars came into play. Future 21-cm observations could thus constrain the energetics of the first supernovae and provide information on the magnetic fields in the primordial IGM.