# Evidence that the AGN dominates the radio emission in z ~ 1 radio-quiet   quasars

**Authors:** Sarah V. White, Matt J. Jarvis, Eleni Kalfountzou, Martin J., Hardcastle, Aprajita Verma, Jos\'e M. Cao Orjales, Jason Stevens

arXiv: 1702.00904 · 2017-02-06

## TL;DR

This study demonstrates that in z ~ 1 radio-quiet quasars, the radio emission is predominantly driven by accretion processes rather than star formation, based on high-sensitivity radio and infrared observations.

## Contribution

It provides the first evidence at this redshift that accretion dominates radio emission in RQQs, using combined JVLA and Herschel data to distinguish emission sources.

## Key findings

- 92% of RQQs are accretion-dominated in radio emission
- Accretion accounts for 80% of total radio luminosity in the sample
- Radio emission correlates with optical luminosity, indicating a link to accretion processes

## Abstract

In order to understand the role of radio-quiet quasars (RQQs) in galaxy evolution, we must determine the relative levels of accretion and star-formation activity within these objects. Previous work at low radio flux-densities has shown that accretion makes a significant contribution to the total radio emission, in contrast with other quasar studies that suggest star formation dominates. To investigate, we use 70 RQQs from the Spitzer-Herschel Active Galaxy Survey. These quasars are all at $z$ ~ 1, thereby minimising evolutionary effects, and have been selected to span a factor of ~100 in optical luminosity, so that the luminosity dependence of their properties can be studied. We have imaged the sample using the Karl G. Jansky Very Large Array (JVLA), whose high sensitivity results in 35 RQQs being detected above 2 $\sigma$. This radio dataset is combined with far-infrared luminosities derived from grey-body fitting to Herschel photometry. By exploiting the far-infrared--radio correlation observed for star-forming galaxies, and comparing two independent estimates of the star-formation rate, we show that star formation alone is not sufficient to explain the total radio emission. Considering RQQs above a 2-$\sigma$ detection level in both the radio and the far-infrared, 92 per cent are accretion-dominated, and the accretion process accounts for 80 per cent of the radio luminosity when summed across the objects. The radio emission connected with accretion appears to be correlated with the optical luminosity of the RQQ, whilst a weaker luminosity-dependence is evident for the radio emission connected with star formation.

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Source: https://tomesphere.com/paper/1702.00904