X-ray properties of the youngest radio sources and their environments

We present the first results from our X-ray study of young radio sources classified as Compact Symmetric Objects (CSOs). Using the Chandra X-ray Observatory we observed six CSOs for the first time in X-rays, and re-observed four CSOs with previous XMM-Newton or Beppo-SAX data. We also included six other CSOs with the archival data to built a pilot sample of the 16 CSO sources observed in X-rays to date. All the sources are nearby, $z<1$, and the age of their radio structures, $<3000$ years, has been derived from the hotspots advance velocity. Our results show heterogeneous nature of the CSOs X-ray emission indicating a complex environment associated with young radio sources. The sample covers a range in X-ray luminosity, $L_{2-10 \rm keV} \sim 10^{41}$-$10^{45}$ erg s$^{-1}$, and intrinsic absorbing column density of $N_H \simeq 10^{21}$-10$^{22}$ cm$^{-2}$. In particular, we detected extended X-ray emission in 1718$-$649, a hard photon index of $\Gamma = 0.8^{+0.3}_{-0.2}$ in 2021$+$614 consistent with either a Compton thick absorber or non-thermal emission from compact radio lobes; an ionized iron emission line, $E_{rest}=(6.62\pm0.04)$ keV, $EW=154^{+65}_{-58}$ eV (for a power law and a Gaussian line model), in 0710$+$439; and the 2-10 keV X-ray flux decrease by an order of magnitude since the 2008 XMM-Newton observation in 1607$+$26. We conclude that our pilot study of CSOs provides a variety of exceptional diagnostics and highlights the importance of deep X-ray observations of large samples of young sources. This is necessary in order to constrain theoretical models for the earliest stage of radio source evolution and study the interactions of young radio sources with the interstellar environment of their host galaxies.