Kinematics and Dynamics of kiloparsec-scale Jets in Radio Galaxies with SKA

TL;DR

This paper discusses how SKA can be used to study the physical properties of kiloparsec-scale jets in radio galaxies, focusing on their dynamics, composition, and velocity fields through high-resolution radio imaging.

Contribution

It introduces new methods for modeling AGN jets as symmetrical relativistic flows and outlines observational strategies with SKA to analyze jet behavior and properties.

Findings

Developed modeling techniques for AGN jets using radio images.

Proposed SKA observations to distinguish jet types and measure their physical parameters.

Identified technical requirements for SKA to resolve jet velocity fields and structures.

Abstract

We explore the use of SKA to deduce the physical parameters of kiloparsec-scale jet flows in radio galaxies. Jets in Active Galactic Nuclei are relativistic where they are first formed, but their speeds and compositions change as they propagate. It has long been known that kiloparsec-scale jets in radio galaxies can be divided into two flavours: strong (found in powerful sources, narrow and terminating in compact hot-spots) and weak (found in low-luminosity sources, geometrically flaring, unable to form hot-spots and terminating in diffuse lobes or tails). We have developed methods to model AGN jets as intrinsically symmetrical, relativistic flows by fitting to deep, well-resolved radio images in Stokes I, Q and U. This has yielded a wealth of information about the brightest few weak-flavour jets. Our first key objective is to observe large samples of weak and transition jets at 0.1 - 0.5 arcsec resolution with SKA1-MID. This would allow us to see how jet propagation depends on power and environment and to quantify the energy and momentum input into the IGM. We will require typical noise levels of 1 microJy/beam, and may be able to exploit survey imaging in some cases. Our second, more challenging, application is to determine the velocity fields in strong-flavour jets. Do they have very fast spines with bulk Lorentz factors of 5 - 10? Is there evidence for magnetic confinement by a toroidal field? What are their energy fluxes? This is a major imaging challenge for SKA2: we need resolution better than 0.05 arcsec, ideally in the 1 - 10 GHz frequency range, with rms noise levels of roughly 10 nJy/beam and extremely high dynamic range, imaging fidelity and polarization purity.