Active Galactic Nuclei in Dusty Starbursts at z = 2: Feedback Still to Kick in

Abstract

We investigate a sample of 152 dusty sources at 1.5 < z < 2.5 to understand the connection of enhanced star formation rate (SFR) and black hole accretion rate. The sources are Herschel-selected, having stellar masses M _* > 10¹⁰ M _⊙ and SFR (∼100-1000 M _⊙ yr^-1) elevated (>4×) above the star-forming “main sequence,” classifying them as starbursts (SBs). Through a multiwavelength fitting approach (including a dusty torus component), we divided the sample into active SBs (dominated by an active galactic nucleus (AGN) emission, SBs-AGN, ∼23% of the sample) and purely star-forming SBs (SBs-SFR). We visually inspected their Hubble Space Telescope/ultraviolet (UV) rest frame maps: SBs-SFR are generally irregular and composite systems; ∼50% of SBs-AGN are instead dominated by regular compact morphologies. We then found archival Atacama Large Millimeter/submillimeter Array continuum counterparts for 33 galaxies (12 SBs-AGN and 21 SBs-SFR). For these sources we computed dust masses, and, with standard assumptions, we also guessed total molecular gas masses. SBs turn into gas-rich systems (f _gas = M _gas/(M _gas + M _*) ≃ 20%-70%), and the gas fractions of the two SB classes are very similar (f _gas = 43% ± 4% and f _gas = 42% ± 2%). Our results show that SBs are consistent with a mixture of: (1) highly star-forming merging systems (dominating the SBs-SFR) and (2) primordial galaxies, rapidly growing their M _* together with their black hole (mainly the more compact SBs-AGN). Feedback effects have not yet reduced their f _gas. Indeed, SBs at z = 2, with relatively low bolometric AGN luminosities in the range 10⁴⁴ < L _bol(AGN) < 10⁴⁶ erg s^-1 (compared to bright optical and X-ray quasars), are still relatively far from the epoch when the AGN feedback will quench the SFR in the host and will substantially depress the gas fractions.