A Sino-German 6cm polarization survey of the Galactic plane VII. Small supernova remnants

TL;DR

This study analyzes the spectral and polarization properties of 50 small supernova remnants using 6cm survey data, providing improved spectra, polarization images, and insights into their nature and magnetic fields.

Contribution

It presents new polarization images for 24 SNRs, refines spectra for several remnants, and identifies G16.8-1.1 as likely an HII region, advancing understanding of small SNRs in the Galactic plane.

Findings

Polarized emission detected in 25 SNRs.

Spectral indices obtained for most SNRs, except Cas A.

G16.8-1.1 likely an HII region, not an SNR.

Abstract

We study the spectral and polarization properties of supernova remnants (SNRs) based on our 6cm survey data. The observations were taken from the Sino-German 6cm polarization survey of the Galactic plane. By using the integrated flux densities at 6cm together with measurements at other wavelengths from the literature we derive the global spectra of 50 SNRs. In addition, we use the observations at 6cm to present the polarization images of 24 SNRs. We derived integrated flux densities at 6cm for 51 small SNRs with angular sizes less than 1 degree. Global radio spectral indices were obtained in all the cases except for Cas A. For SNRs G15.1-1.6, G16.2-2.7, G16.4-0.5, G17.4-2.3, G17.8-2.6, G20.4+0.1, G36.6+2.6, G43.9+1.6, G53.6-2.2, G55.7+3.4, G59.8+1.2, G68.6-1.2, and G113.0+0.2, the spectra have been significantly improved. From our analysis we argue that the object G16.8-1.1 is probably an HII region instead of a SNR. Cas A shows a secular decrease in total intensity, and we measured a flux density of 688+/-35 Jy at 6cm between 2004 and 2008. Polarized emission from 25 SNRs were detected. For G16.2-2.7, G69.7+1.0, G84.2-0.8 and G85.9-0.6, the polarized emission is detected for the first time confirming them as SNRs. High frequency observations of SNRs are rare but important to establish their spectra and trace them in polarization in particular towards the inner Galaxy where Faraday effects are important.