Non-Thermal Radio and Gamma-Ray Emission from a Supernova Remnant by the Blast Wave Breaking Out of the Circumstellar Matter

Abstract

We calculate synchrotron radio emission and gamma-ray emission due to bremsstrahlung, inverse-Compton scattering and pi0-decay from the remnant of supernova which exploded in the circumstellar matter (CSM) formed by the progenitor's stellar wind. This sort of situation is a possible origin of mixed-morphology supernova remnants (SNRs) like W49B, which exhibit recombination-radiation spectra in X-ray emission. We assume that the CSM of 1.5 Modot exists at 0.07--3 pc away from the supernova in the interstellar medium (ISM) of density 0.016 cm-3. When the blast wave breaks out of the CSM into the ISM, its velocity rapidly increases and hence particle acceleration is enhanced. The maximum energy of protons reaches sim 1300 TeV just after the break-out with sim 0.5% of the explosion energy. We consider the non-thermal emission from the blast-shocked ISM shell after the break-out. Synchrotron radio flux at 1 GHz is tens Jy, comparable to the observed from mixed-morphology SNRs. Because of low density, the gamma-ray luminosity is dominated by inverse-Compton scattering, which is higher than the pi0-decay luminosity by an order of magnitude. The total gamma-ray luminosity including bremsstrahlung is of the order of 1033 erg s-1 lower than the typical value 1035--1036 erg s-1 observed from mixed-morphology SNRs. However, if, e.g., sim10% of accelerated protons interact with some matter of density sim100 cm-3, pi0-decay gamma-ray luminosity would be enhanced to be comparable with the observed value.