ALMA Observations of a Candidate Molecular Outflow in an Obscured Quasar

Abstract

We present Atacama Large Millimeter/Submillimeter Array (ALMA) CO (1-0) and CO (3-2) observations of SDSS J135646.10+102609.0, an obscured quasar and ultra-luminous infrared galaxy (ULIRG) with two merging nuclei and a known 20-kpc-scale ionized outflow. The total molecular gas mass is Mmol ~ 9+19-6 x 108 Msun, mostly distributed in a compact rotating disk at the primary nucleus (Mmol ~ 3 x 108 Msun) and an extended tidal arm (Mmol ~ 5 x 108 Msun). The tidal arm is one of the most massive molecular tidal features known; we suggest that it is due to the lower chance of shock dissociation in this elliptical/disk galaxy merger. In the spatially resolved CO (3-2) data, we find a compact (r ~ 0.3 kpc) high velocity (v ~ 500 km/s) red-shifted feature in addition to the rotation at the N nucleus. We propose a molecular outflow as the most likely explanation for the high velocity gas. The outflowing mass of Mmol ~ 7 x 107 Msun and the short dynamical time of tdyn ~ 0.6 Myr yield a very high outflow rate of Mmol ~ 350 Msun/yr and can deplete the gas in a million years. We find a low star formation rate (< 16 Msun/yr from the molecular content and < 21 Msun/yr from the far-infrared spectral energy distribution decomposition) that is inadequate to supply the kinetic luminosity of the outflow (E ~ 3 x 1043 erg/s). Therefore, the active galactic nucleus, with a bolometric luminosity of 1046 erg/s, likely powers the outflow. The momentum boost rate of the outflow (p/(Lbol/c) ~ 3) is lower than typical molecular outflows associated with AGN, which may be related to its compactness. The molecular and ionized outflows are likely two distinct bursts induced by episodic AGN activity that varies on a time scale of 107 yr.