The Origin of High Energy Emission in the Young Radio Source PKS 1718-649

TL;DR

This paper models the broadband emission of the young radio source PKS 1718-649, explaining its gamma-ray and X-ray emissions and providing insights into its jet power, environment, and accretion processes.

Contribution

It offers a detailed spectral energy distribution model for PKS 1718-649, linking gamma-ray and X-ray emissions to specific physical mechanisms and environmental conditions.

Findings

Gamma-ray emission explained by inverse Compton scattering of UV photons.

X-ray emission likely involves additional mechanisms like a weak corona.

Jet power estimated at approximately 2.2 x 10^{42} erg/s.

Abstract

We present a model for the broadband radio-to-$\gamma$-ray spectral energy distribution of the compact radio source, PKS 1718-649. Because of its young age (100 years) and proximity ($z=0.014$), PKS 1718-649 offers a unique opportunity to study nuclear conditions and the jet/host galaxy feedback process at the time of an initial radio jet expansion. PKS 1718-649 is one of a handful of young radio jets with $\gamma$-ray emission confirmed with the Fermi/LAT detector. We show that this $\gamma$-ray emission can be successfully explained by Inverse Compton scattering of the ultraviolet photons, presumably from an accretion flow, off non-thermal electrons in the expanding radio lobes. The origin of the X-ray emission in PKS 1718-649 is more elusive. While Inverse Compton scattering of the infrared photons emitted by a cold gas in the vicinity of the expanding radio lobes contributes significantly to the X-ray band, the data require that an additional X-ray emission mechanism is at work, e.g. a weak X-ray corona or a radiatively inefficient accretion flow, expected from a LINER type nucleus such as that of PKS 1718-649. We find that the jet in PKS 1718-649 has low power, $L_j \simeq 2.2 \times 10^{42}$ erg s$^{-1}$, and expands in an environment with density $n_0 \simeq 20$ cm$^{-3}$. The inferred mass accretion rate and gas mass reservoir within 50-100 pc are consistent with estimates from the literature obtained by tracing molecular gas in the innermost region of the host galaxy with SINFONI and ALMA.