Characteristics of remnant radio galaxies detected in the deep radio continuum observations from the SKA pathfinders

TL;DR

This study investigates the properties and evolution of remnant radio galaxies using deep radio observations from SKA pathfinders, revealing diverse morphologies, spectral ages, and insights into their lifecycle and environmental effects.

Contribution

The paper presents new low-frequency radio observations and spectral modeling of five remnant radio galaxies, providing novel insights into their ages, morphologies, and evolutionary phases.

Findings

All remnants show low-surface-brightness emission.

Discovery of wing-shaped radio morphology in one source.

Spectral ages range from 20.3 to 41.4 million years.

Abstract

The cessation of AGN activity in radio galaxies leads to a remnant phase during which jets are no longer sustained, but lobes can be detected for a period of time before they fade away due to radiative and dynamical energy losses. The time-scale of the remnant phase and AGN duty cycle are vital to understanding the evolution of radio galaxies. In this paper, we report new band-3 observations with the upgraded Giant Meterwave Radio Telescope (uGMRT) for five remnant radio galaxies. Our uGMRT observations reveal emission of low-surface-brightness in all five remnants with 400 MHz surface brightness in the range of 36$-$201 mJy arcmin$^{-2}$. With band-3 uGMRT observations, we discover wing-shaped radio morphology in one of our sample sources. Using radio observations at 150 MHz, 325 MHz, 400 MHz, and 1.5 GHz, we model the radio spectral energy distributions (SEDs) of our sample sources with the continuous injection-off model (CI$_{\rm OFF}$), that assumes an active phase with continuous injection followed by a remnant phase. We obtain total source ages ($t_{\rm s}$) in the range of 20.3 Myr to 41.4 Myr with $t_{\rm OFF}$/$t_{\rm s}$ distributed in the range of 0.16 to 0.63, which in turn suggests them to belong to different evolutionary phases. We note that, in comparison to the remnants reported in the literature, our sample sources tend to show lower spectral ages that can be explained by the combined effects of more dominant inverse Compton losses for our sources present at the relatively higher redshifts and possible rapid expansion of lobes in their less dense environments.