CHANG-ES VI: Probing Supernova Energy Deposition in Spiral Galaxies Through Multi-Wavelength Relationships

Abstract

How a galaxy regulates its SNe energy into different interstellar/circumgalactic medium components strongly affects galaxy evolution. Based on the JVLA D-configuration C- (6 GHz) and L-band (1.6 GHz) continuum observations, we perform statistical analysis comparing multi-wavelength properties of the CHANG-ES galaxies. The high-quality JVLA data and edge-on orientation enable us for the first time to include the halo into the energy budget for a complete radio-flux-limited sample. We find tight correlations of L radio with the mid-IR-based SFR. The normalization of our I 1.6GHz/ W~Hz-1- SFR relation is 2-3 times of those obtained for face-on galaxies, probably a result of enhanced IR extinction at high inclination. We also find tight correlations between L radio and the SNe energy injection rate E SN(Ia+CC), indicating the energy loss via synchrotron radio continuum accounts for 0.1\% of E SN, comparable to the energy contained in CR electrons. The integrated C-to-L-band spectral index is α0.5-1.1 for non-AGN galaxies, indicating a dominance by the diffuse synchrotron component. The low-scatter L radio- SFR/L radio-E SN (Ia+CC) relationships have super-linear logarithmic slopes at 2~σ in L-band (1.1320.067/1.1750.102) while consistent with linear in C-band (1.0570.075/1.1000.123). The super-linearity could be naturally reproduced with non-calorimeter models for galaxy disks. Using Chandra halo X-ray measurements, we find sub-linear L X-L radio relations. These results indicate that the observed radio halo of a starburst galaxy is close to electron calorimeter, and a galaxy with higher SFR tends to distribute an increased fraction of SNe energy into radio emission (than X-ray).