English

Cosmic ray protons and electrons from supernova remnants

High Energy Astrophysical Phenomena 2021-06-23 v1

Abstract

The spectrum of cosmic ray protons and electrons released by supernova remnants throughout their evolution is poorly known, because of the difficulty in accounting for particle escape and confinement in the downstream of a shock front, where both adiabatic and radiative losses are present. Here we calculate the spectrum of cosmic ray protons released during the evolution of supernovae of different types, accounting for the escape from upstream and for adiabatic losses of particles advected downstream of the shock and liberated at later times. The same calculation is carried out for electrons. The magnetic field in the post-shock region is calculated by using an analytic treatment of the magnetic field amplification due to non--resonant and resonant streaming instability and their saturation. We find that when the field is the result of the growth of the cosmic-ray--driven non--resonant instability alone, the spectrum of electrons and protons released by a supernova remnant are indeed different, but such a difference becomes appreciable only at energies 1001000\gtrsim 100-1000 GeV, while observations of the electron spectrum require such a difference to be present at energies as low as 10\sim 10 GeV. An effect at such low energies requires substantial magnetic field amplification in the late stages of the supernova remnant evolution (shock velocity 1000\ll 1000 km/s), perhaps not due to streaming instability but hydrodynamical processes. We comment on the feasibility of such conditions and speculate on the possibility that the difference in spectral shape between electrons and protons may reflect either some unknown acceleration effect, or additional energy losses in cocoons around the sources.

Keywords

Cite

@article{arxiv.2103.02375,
  title  = {Cosmic ray protons and electrons from supernova remnants},
  author = {P. Cristofari and P. Blasi and D. Caprioli},
  journal= {arXiv preprint arXiv:2103.02375},
  year   = {2021}
}

Comments

11 pages, 5 figures, Accepted for publication in Astronomy \& Astrophysics

R2 v1 2026-06-23T23:42:31.687Z