Hubble Space Telescope Wide Field Camera 3 Identifies an $r_p$ = 1 Kpc Dual Active Galactic Nucleus in the Minor Galaxy Merger SDSS J0924+0510 at z = 0.1495

TL;DR

This study used Hubble Space Telescope imaging to identify a dual active galactic nucleus separated by about 1 kiloparsec in a galaxy merger, demonstrating a method to detect close dual AGNs that might be missed by less sensitive observations.

Contribution

The paper presents a new high-resolution imaging approach combining near-infrared and optical data to identify close dual AGNs at advanced merger stages.

Findings

Identified a dual AGN with a 1 kpc separation in galaxy SDSS J0924+0510.

Showed that combining NIR and optical imaging effectively distinguishes dual AGNs from other scenarios.

Suggested that many close dual AGNs may be missed in low-resolution surveys.

Abstract

Kiloparsec-scale dual active galactic nuclei (AGNs) are active supermassive black hole pairs co-rotating in galaxies with separations of less than a few kpc. Expected to be a generic outcome of hierarchical galaxy formation, their frequency and demographics remain uncertain. We have carried out an imaging survey with the Hubble Space Telescope (HST) Wide Field Camera 3 (WFC3) of AGNs with double-peaked narrow [O III] emission lines. HST/WFC3 offers high image quality in the near-infrared (NIR) to resolve the two stellar nuclei, and in the optical to resolve [O III] from ionized gas in the narrow-line regions. This combination has proven to be key in sorting out alternative scenarios. With HST/WFC3 we are able to explore a new population of close dual AGNs at more advanced merger stages than can be probed from the ground. Here we show that the AGN SDSS J0924+0510, which had previously shown two stellar bulges, contains two spatially distinct [O III] regions consistent with a dual AGN. While we cannot completely exclude cross-ionization from a single central engine, the nearly equal ratios of [O III] strongly suggest a dual AGN with a projected angular separation of 0."4, corresponding to a projected physical separation of $r_p$ = 1 kpc at redshift z = 0.1495. This serves as a proof of principle for combining high-resolution NIR and optical imaging to identify close dual AGNs. Our result suggests that studies based on low-resolution and/or low-sensitivity observations may miss close dual AGNs and thereby may underestimate their occurrence rate on $\lesssim$ kpc scales.