GATOS. n. On the physical origin of the extended MIR emission in AGN (2507.19350v1)

Abstract: The polar mid-infrared (MIR) emission detected from tens to hundreds of parsecs in some active galactic nuclei (AGN) has been associated with dusty winds driven away by radiation pressure. However, the physical characterization of this extended polar emission remains uncertain. Here we combine $10-21\mu$m JWST/MIRI imaging observations with $7-25 \mu$m MRS integral field spectroscopic observations of 6 nearby, $\bar{D}=35.4\pm4.6$~Mpc, AGN from the GATOS Survey to quantify the nature of the extended MIR emission at $\sim75$ pc resolution at $21~\mu$m. These AGN have similar bolometric luminosities, $\log_{10}(\bar{L}{\rm{bol}}~[\rm{erg\,s}^{-1}])=44.0\pm0.3$, span a wide range of optical outflow rates, $\dot{M}=0.003-0.21$ M${\odot}$ yr$^{-1}$, column densities, $\log_{10}(N_{H}^{X-ray} [cm^{-2}])=22.2-24.3$, and Eddington ratios, $\lambda_{\rm{Edd}}=0.005-0.06$. We find a poor correlation between the line-only and continuum-only images, indicating that the extended MIR continuum emission is spatially uncorrelated with the warm outflows associated with narrow emission lines in the $10-15\,\mu$m wavelength range. The $75-450$~pc continuum emission has constant dust temperature, $T_{\rm{d}}=132^{+7}_{-7}$ K, and mass, $M_{\rm{d}}=728^{+29}_{-27}$ M$_{\odot}$. Using the conditions of energy balance between radiation pressure and gravity, we find that our AGN sample is in the gravitationally bounded regime, consistent with the lack of detection of dusty winds in our observations. At $10~\mu$m, the level of line emission contribution across the NLR is correlated with the outflow kinetic energy and mass outflow rates. We find no correlation with the AGN properties. These results indicate that the radio jet may be triggering the gas outflow and line emission, while the extended dust emission is distributed in molecular clouds and/or shocked regions across the narrow line region.