MIRACLE III. JWST/MIRI expose the hidden role of the AGN outflow in NGC 1068

TL;DR

This study uses JWST MIRI and MUSE observations to reveal the complex multi-phase structure and dynamics of the AGN outflow in NGC 1068, highlighting the significant hidden ionized gas mass and the outflow's impact on the host galaxy.

Contribution

It introduces combined Mid-IR and optical integral field spectroscopy to analyze AGN outflows, revealing a two-stage acceleration and hidden ionized gas components not seen in optical diagnostics.

Findings

Mid-IR diagnostics identify high-density clumps along the jet edges.

Outflow velocities differ between [OIV] and [OIII], indicating distinct gas components.

Most outflowing ionized gas mass is hidden from optical observations.

Abstract

We present new JWST IFS observations of the active galaxy NGC 1068, combining Mid-IR and optical IFS data from MIRI and MUSE to characterize the multi-phase circumnuclear gas properties and its interaction with the AGN outflow and radio jet. MIRI data trace the multiphase gas emission up to 400 pc from the nucleus at 20--60 pc resolution, unveiling a clumpy ionized structure around the radio hot-spots and a rotating warm molecular disc. Innovative Mid-IR diagnostic diagrams highlight the role of the AGN as the main excitation source for the ionized gas in the entire MIRI field of view, consistent with optical diagnostics, and supporting the AGN-driven wind scenario. Density sensitive [NeV] and [ArV] Mid-IR transitions reveal high-density clumps (n_e > 10**4 cm**-3) along the edges of the jet and outflow, tracing gas compression by the expanding wind. We combined multi-cloud kinematic (MOKA) and photo-ionization (HOMERUN) modeling to characterize the ionized outflow properties and found that [OIV] traces an outflow 300 km/s faster than that inferred from [OIII], showing that the two lines originate from distinct gas components. This kinematic dichotomy is confirmed by the photoionization analysis, which requires a dust-poor component dominating the optical lines and a dust-rich component responsible for the Mid-IR emission. The Mid-IR-revealed dusty component carries a significantly larger ionized-gas mass than what can be inferred from optical lines alone, showing that most of the outflowing mass is hidden from classical optical diagnostics. Our modelling point to a two-stage acceleration scenario, with velocities up to ~2000 km/s, consistent with an energy-driven wind. Our findings indicates that the outflow entrains up to a few 10**6 solar masses of ionized gas and couples efficiently with the surrounding ISM, injecting turbulence and impacting the host-galaxy environment.