Feeding Versus Feedback in AGNs from Near-Infrared IFU Observations: The Case of Mrk 766

TL;DR

This study uses near-infrared integral field spectroscopy to map the emission-line fluxes, ratios, and gas kinematics in the inner 450 pc of Seyfert galaxy Mrk 766, revealing complex excitation mechanisms, gas dynamics, and outflows.

Contribution

First detailed near-IR IFU mapping of Mrk 766's inner region, analyzing excitation, kinematics, and outflows with high spatial and velocity resolution.

Findings

Ionized and molecular gas extend up to 300 pc from nucleus.

Radio jet influences gas excitation and kinematics.

Detected outflow with a rate of ~10 solar masses per year.

Abstract

We have mapped the emission-line flux distributions and ratios as well as the gaseous kinematics of the inner 450 pc radius of the Seyfert 1 galaxy Mrk 766 using integral field near-IR J- and Kl-band spectra obtained with the Gemini nifs at a spatial resolution of 60 pc and velocity resolution of 40 km/s. Emission-line flux distributions in ionized and molecular gas extend up to ~ 300 pc from the nucleus. Coronal [S IX]{\lambda}1.2523{\mu}m line emission is resolved, being extended up to 150 pc from the nucleus. At the highest flux levels, the [Fe II]{\lambda}1.257{\mu}m line emission is most extended to the south-east, where a radio jet has been observed.The emission-line ratios [Fe II]{\lambda}1.2570{\mu}m/Pa{\beta} and $H_2${\lambda}2.1218{\mu}m/Br{\gamma} show a mixture of Starburst and Seyfert excitation; the Seyfert excitation dominates at the nucleus, to the north-west and in an arc-shaped region between 0.2" and 0.6" to the south-east at the location of the radio jet. A contribution from shocks at this location is supported by enhanced [Fe II]/[P II] line ratios and increased [Fe II] velocity dispersion. The gas velocity field is dominated by rotation that is more compact for $H_2$ than for Pa{\beta}, indicating that the molecular gas has a colder kinematics and is located in the galaxy plane. There is about $10^3$ solar masses of hot $H_2$, implying ~ $10^9$ solar masses of cold molecular gas. At the location of the radio jet, we observe an increase in the [Fe II] velocity dispersion (150 km/s), as well as both blueshift and redshifts in the channel maps, supporting the presence of an outflow there. The ionized gas mass outflow rate is estimated to be ~ 10 solar masses/yr, and the power of the outflow ~ 0.08 $L_{bol}$.