The black hole-star formation connection over cosmic time

TL;DR

This paper models how active galactic nuclei (AGN) influence star formation over cosmic time, revealing phases of enhancement and suppression due to jet feedback, and predicting their environmental dependence.

Contribution

It introduces a simplified model incorporating AGN jet feedback that explains diverse star formation behaviors and their evolution in the SFR-stellar mass plane.

Findings

Jetted AGN can both enhance and suppress star formation.

Jet feedback causes characteristic movements in the SFR-stellar mass plane.

Model predicts environmental dependence of black hole-star formation connection.

Abstract

Observations at low redshift have begun to tease out the star formation rate in active galaxies (AGN), which marks the beginning of the black hole-star formation connection over cosmic time. Star formation appears to depend on AGN type, cluster richness, and black hole accretion, but in ways that are not direct and have yet to be understood. Much of the confusion is that while some AGN appear to enhance star formation, others seem to suppress it. By implementing simplified, yet informed assumptions about AGN feedback on star formation, we show how AGN with jets might be dominated by two phases in which star formation is first enhanced, then suppressed. With this new element incorporated into our model, we make sense of radio and quasar mode behavior in the star formation rate-stellar mass (SFR-SM) plane for AGN. Due to jet feedback on star formation, jetted AGN tend to move upwards and rightward in the SFR-SM plane and then downward and to the right, past both the star-forming main sequence (SFMS) as well as the radio-quiet AGN. This picture allows us to predict the black hole connection to star formation as a function of the environment over the history of the universe.