Radio spectral properties at 150-5000MHz of star-forming galaxies in the ELAIS-N1 field
First author: Fangxia An
By combining high-sensitivity LOFAR 150MHz, uGMRT 400MHz, GMRT 610MHz, and JVLA 5GHz data in the ELAIS-N1 field, we study the radio spectral properties of radio-detected star-forming galaxies (SFGs) at observer-frame frequencies of 150-5000MHz. We select ~3,500 SFGs that have both LOFAR 150MHz and GMRT 610MHz detections by removing AGN from the two radio samples, and obtain a median spectral index of $\alpha_{150}^{610}=-0.51\pm0.01$ with a scatter of $\sigma=0.2$. Due to the relatively lower sensitivity of uGMRT 400MHz data, we apply a flux cut of $S_{610}>300\mu$Jy and obtain the median spectral indices of $\alpha_{150}^{385}=-0.42^{+0.03}{-0.02}$, $\alpha{385}^{610}=-0.44^{+0.03}{-0.04}$, and $\alpha{150}^{610}=-0.42^{+0.02}{-0.01}$ for the sample of 258 SFGs that have detections at these three radio frequencies. The JVLA 5GHz observations only cover the central 0.1deg$^{2}$, where ~100 SFGs are selected, for which we obtain median $\alpha{610}^{5000}=-1.14^{+0.04}{-0.05}$, $\alpha{385}^{5000}=-1.08^{+0.01}{-0.02}$ and $\alpha{150}^{5000}=-0.87\pm0.01$. Overall, the results show that the radio spectrum is flatter if we include a lower frequency dataset when measuring the radio spectral index at 150-5000MHz. We study the correlations between radio spectral index and physical properties of radio-selected SFGs and find that, on average, the radio spectrum slightly steepens with increasing stellar mass. However, we only find that the radio spectrum flattens with increasing optical depth at V-band at $\nu<\sim1$GHz. We suggest that spectral ageing due to the energy loss of cosmic ray electrons and thermal free-free absorption could be among the most likely physical mechanisms that drive the two correlations respectively. Both of these could be the physical causes of why the radio spectrum is flatter at low frequency than at high frequency.