The Multi-phase Biconical Outflow in the local IR-Luminous Merger IRASF01364-1042

Abstract

We investigate the spatially-resolved ISM properties of the local (z = 0.048), IR-luminous (L IR = 1011.87\,L), late-stage galaxy merger IRAS F01364-1042, combining multi-wavelength IFU observations from JWST/MIRI-MRS, ALMA and Keck/KCWI. Using these datasets, we construct emission line maps of several key tracers of the ionized (e.g., [Ne\,II]\,12.8μm, [O\,III]λ5007), warm molecular (e.g., H2\,0-0\,S(3)), and cold molecular gas (e.g., CO (J=2-1)), and perform detailed decomposition of spectra extracted in resolved regions across the areas of emission. We confirm the presence of a multi-phase galactic biconical outflow along the minor axis of a highly inclined rotating disk. The inferred outflow velocities are \,500 - 600\,km\,s-1 \,350\,km\,s-1, and \,200 - 300\,km\,s-1, in the ionized, warm and cold molecular phase, respectively, with corresponding mass outflow rates of 0.3 - 2.3, 31, and 38 - 240\,M\,yr-1. The cold molecular phase dominates both the total mass outflow rate and the associated kinetic energy (\,2 - 8 × 1042\,erg\,s-1). We confirm, for the first time, a dust-obscured AGN in IRAS\,F01364-1042, via detection of the [Ne\,V]\,14.3μm line. The low inferred AGN bolometric luminosity (1.2 - 1.8 × 1043\,erg\,s-1) suggests that the nuclear starburst alone, with a star formation rate of 40 - 60\,M\,yr-1, can account for the energy required to drive the outflow, though a more active AGN phase in the recent past may have also played a role. Our work showcases the necessity of multi-wavelength observations for interpreting the gas dynamics in merger-driven dusty starbursts, and the capability of JWST/MIRI-MRS to uncover obscured, low-luminosity AGN that may be common in these systems.