AGN duty cycle estimates for the ultra-steep spectrum radio relic VLSS J1431.8+1331

TL;DR

This study characterizes the spectral properties and estimates the age of the radio relic VLSS J1431+1331 using multi-frequency data, revealing insights into the AGN duty cycle and the source's complex morphology.

Contribution

It provides the first detailed spectral and age analysis of VLSS J1431+1331, constraining its activity history and suggesting it is a relic with a potentially shocked plasma component.

Findings

AGN activity likely ceased around 60 Myr ago

The source has a two-component structure with distinct spectral properties

The larger component may host a faint radio core, indicating a relic origin

Abstract

Steep spectrum radio sources associated with active galactic nuclei (AGN) may contain remnants of past AGN activity episodes. Novel instruments like the LOw Frequency ARray (LOFAR) are enabling studies of these fascinating structures to be made at tens to hundreds of MHz with sufficient resolution to analyse their complex morphology. Our goal is to characterize the integrated and resolved spectral properties of VLSS J1431+1331 and estimate source ages based on synchrotron radio emission models, thus putting constraints on the AGN duty cycle. Using a broad spectral coverage, we have derived spectral and curvature maps, and used synchrotron ageing models to determine the time elapsed from the last time the source plasma was energized. We used LOFAR, Giant Metrewave Radio Telescope (GMRT) and Jansky Very Large Array (VLA) data. Based on our ageing analysis, we infer that the AGN that created this source currently has very low levels of activity or that it is switched off. The derived ages for the larger source component range from around 60 to 130 Myr, hinting that the AGN activity decreased or stopped around 60 Myr ago. Our analysis suggests that VLSS J1431.8+1331 is an intriguing, two-component source. The larger component seems to host a faint radio core, suggesting that the source may be an AGN radio relic. The spectral index we observe from the smaller component is distinctly flatter at lower frequencies than the spectral index of the larger component, suggesting the possibility that the smaller component may be a shocked plasma bubble. From the integrated source spectrum, we deduce that its shape and slope can be used as tracers of the activity history of this type of steep spectrum radio source.