Spectral softening in core-collapse supernova remnant expanding inside wind-blown bubble

TL;DR

This study models particle acceleration in a core-collapse supernova remnant within a wind-blown bubble, revealing spectral softening and emission features influenced by complex shock interactions and magnetic fields.

Contribution

It provides a detailed simulation of cosmic ray spectra and emission in a realistic supernova environment, highlighting the impact of shock interactions and magnetic fields on spectral features.

Findings

Particle spectra are softer with indices near 2.5 during shock propagation.

The total cosmic ray spectrum aligns with galactic CR injection spectra.

Magnetic fields significantly influence emission morphology.

Abstract

Context. Galactic cosmic rays are widely assumed to arise from diffusive shock acceleration, specifically at shocks in supernova remnants (SNRs). These shocks expand in a complex environment, particularly in the core-collapse scenario as these SNRs evolve inside the wind-blown bubbles created by their progenitor stars. The cosmic rays (CRs) at core-collapse SNRs may carry spectral signatures of that complexity. Aims. We study particle acceleration in the core-collapse SNR of a progenitor with initial mass 60 $M_\odot$ and realistic stellar evolution. The SNR shock interacts with discontinuities inside the wind-blown bubble and generates several transmitted and reflected shocks. We analyse their impact on particle spectra and the resulting emission from the remnant. Methods. The hydrodynamic equations for the evolution of SNR inside the pre-supernova circumstellar medium have been solved simultaneously with the transport equation for cosmic rays in test-particle approximation and with the induction equation for the magnetohydrodynamics (MHD) in 1-D spherical symmetry. Results. The evolution of core-collapse SNRs inside complex wind-blown bubbles modifies the spectra of both the particles and their emission. We have found softer particle spectra with spectral indices close to 2.5 during shock propagation inside the shocked wind, and this softness persists at later evolutionary stages. Further, our calculated total production spectrum released into the interstellar medium demonstrates spectral consistency at high energy with the galactic CRs injection spectrum, required in propagation models. The magnetic field structure effectively influences the emission morphology of SNR as it governs the transportation of particles and the synchrotron emissivity.