AGN photoionization of gas in companion galaxies as a probe of AGN radiation in time and direction

TL;DR

This study uses AGN photoionization of gas in companion galaxies to probe the intensity, direction, and variability of AGN radiation over time, revealing insights into AGN radiation cones and environmental effects.

Contribution

It demonstrates that cross-ionization can be used to study AGN radiation properties independently of host galaxy gas, and identifies candidate systems showing this effect.

Findings

Approximately 30% of candidate systems show signs of cross-ionization.

AGN radiation cones likely have ~70-degree opening angles.

Long-range ionization observed up to 15 kpc from AGN.

Abstract

We consider AGN photoionization of gas in companion galaxies (cross-ionization) as a way to sample the intensity of AGN radiation in both direction and time, independent of the gas properties of the AGN host galaxies. From an initial set of 212 AGN+companion systems, identified with the help of Galaxy Zoo participants, we obtained long-slit optical spectra of 32 pairs which were a priori likely to show cross-ionization based on projected separation or angular extent of the companion. From emission-line ratios, 10 of these systems are candidates for cross-ionization, roughly the fraction expected if most AGN have ionization cones with 70-degree opening angles. Among these, Was 49 remains the strongest nearby candidate. NGC 5278/9 and UGC 6081 are dual-AGN systems with tidal debris, complicating identification of cross-ionization. The two weak AGN in the NGC 5278/9 system ionize gas filaments to a projected radius 14 kpc from each galaxy. In UGC 6081, an irregular high-ionization emission region encompasses both AGN, extending more than 15 kpc from each. The observed AGN companion galaxies with and without signs of external AGN photoionization have similar distributions in estimated incident AGN flux, suggesting that geometry of escaping radiation or long-term variability control this facet of the AGN environment. This parallels conclusions for luminous QSOs based on the proximity effect among Lyman-alpha absorbers. In some galaxies, mismatch between spectroscopic classifications in the common BPT diagram and the intensity of weaker He II and [Ne V] emission lines highlights the limits of common classifications in low-metallicity environments.