4.7 Article

Non-thermal Sunyaev-Zeldovich signal from radio galaxy lobes

Journal

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY
Volume 503, Issue 4, Pages 5473-5484

Publisher

OXFORD UNIV PRESS
DOI: 10.1093/mnras/stab810

Keywords

galaxies: evolution; galaxies: jets; cosmic background radiation

Funding

  1. Department of Atomic Energy, Government of India [12-RD-TFR5.02-0200]
  2. Royal Society

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This study explores the potential impact of high-energy electrons in the lobes of radio galaxies on radio, X-rays, and cosmic microwave background radiation, using an improved model to estimate observational parameters. The research indicates that non-thermal SZ distortions in radio galaxy lobes may have a non-negligible effect on observations, especially for small and young galaxies in cluster environments.
Energetic electrons in the lobes of radio galaxies make them potential sources for not only radio and X-rays but also Sunyaev-Zeldovich (SZ) distortions in the cosmic microwave background (CMB) radiation. Previous works have discussed the energetics of radio galaxy lobes, but assuming thermal SZ, effect, coming from the non-thermal electron population. We use an improved evolutionary model for radio galaxy lobes to estimate the observed parameters such as the radio luminosity and intensity of SZ-distortions at the redshifts of observation. We, further, quantify the effects of various relevant physical parameters of the radio galaxies, such as the jet power, the time-scale over which the jet is active, the evolutionary time-scale for the lobe, etc. on the observed parameters. For current SZ observations towards galaxy clusters, we find that the non-thermal SZ distortions from radio lobes embedded in galaxy clusters can be non-negligible compared to the amount of thermal SZ distortion from the intracluster medium and, hence, cannot be neglected. We show that small and young (and preferably residing in a cluster environment) radio galaxies offer better prospects for the detection of the non-thermal SZ signal from these sources. We further discuss the limits on different physical parameters for some sources for which SZ effect has been either detected or upper limits are available. The evolutionary models enable us to obtain limits, previously unavailable, on the low energy cut-off of electron spectrum (pmin similar to 1-2) in order to explain the recent non-thermal SZ detection. Finally, we discuss how future CMB experiments, which would cover higher frequency bands (>400 GHz), may provide clear signatures for non-thermal SZ effect.

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