Testing the Radio-Selection Method of Dual Active Galactic Nuclei in the Stripe 82 Field

TL;DR

This study tests the radio selection method for dual active galactic nuclei in the Stripe 82 field, confirming some as true dual AGNs and analyzing their properties to understand merger-induced activity.

Contribution

It provides the first confirmation of dual AGNs using high-resolution radio imaging in the Stripe 82 field, and assesses the effectiveness of radio selection for identifying dAGNs.

Findings

6 pairs host two separate radio cores, confirming dual AGNs

Most kinematic pairs show radio power above star-formation levels

Dual AGNs are rare but merger processes influence their triggering

Abstract

We test the merger-induced dual active galactic nuclei (dAGN) paradigm using a sample of 35 radio galaxy pairs from the SDSS Stripe 82 field. Using Keck optical spectroscopy, we confirm 21 pairs have consistent redshifts, constituting kinematic pairs; the remaining 14 pairs are line-of-sight projections. We classify the optical spectral signatures via emission line ratios, equivalent widths, and excess of radio power above star-formation predicted outputs. We find 6 galaxies are classified as LINERs and 7 are AGN/starburst composites. Most of the LINERs are retired galaxies, while the composites likely have AGN contribution. All of the kinematic pairs exhibit radio power more than 10$\times$ above the level expected from just star-formation, suggestive of a radio AGN contribution. We also analyze high-resolution (0.3") imaging at 6 GHz from the NSF's Karl G. Jansky Very Large Array for 17 of the kinematic pairs. We find 6 pairs (2 new, 4 previously known) host two separate radio cores, confirming their status as dAGNs. The remaining 11 pairs contain single AGNs, with most exhibiting prominent jets/lobes overlapping their companion. Our final census indicates a dAGN duty cycle slightly higher than predictions of purely stochastic fueling, although a larger sample (potentially culled from VLASS) is needed to fully address the dAGN fraction. We conclude that while dAGNs in the Stripe 82 field are rare, the merger process plays some role in their triggering and it facilitates low to moderate levels of accretion.